American Dynamics AD1024 Security Camera User Manual
Contents
1. Level 3 6 Bays 75 TERMINATOR 448 INPUTS X 48 OUTPUTS TIMES 11505 gt 56443444 344444 5 66666008 8 50000000 500000000 200000000 23 00000000 zim 6 8 200000000 8 EM GM 560000000 3 eeeoeooo s z 8 500000000 260000006 b 5660660000 8 3 F000000060 5666060060 s 500606000 3 86 5066060000 8 566000000 8 7 860000000 amm E 5600006000 5 Foooo0000 3 560606600002. 2 TE 50 5468 80 2 000200005000 00 2666060006 8 5656066000602 C 566060000 8 5 5 200000009 260600600628 200000000 8 5 200000000 500000000 8 5 266000006 860000000 Sn 360066006 zem 500000000 c 9 5 s 3 5 200000000 Sn 266660600628 50060006 sn 200000000 8 00000000 S 3 300000000 2 54 3 3 802090900 860000000 _ 5 5660600600 lt 800000000 S 3 86600060060 860000000 zamm 2600000000 8 590000000 5 85 550 5488 2 0 m PEE lt 20 02 lt 200 2 6666666666660966 6600000000000000 366000000 8 6666606 y 5600000000 266666666 250660666 256000066 200000000 50660060060 296000006 Be 106660006 8 390000000 Sn 00660600 300000000 8 1600060600 8 7 590000
3. 8 a S E E N a o eats 3 d 280 8018 5 boo 32 9 09000090000050 0000000000000 666660060 8 bo o o oobst cm 6060066066 sn 600660666 60066000 8 5 oeeeeooos s 3 00000000 S 3 5660666006 300000000 s Fooooo000 300000000 s l eoeeeoooz 5 560000000 s 8 60060000 60000000 660066666 8 7 6606660066 8 5660000000 200000000 zim sn 5600000002 325 766660060 8 86606000090 15 500000000 866666600 a 500000000 8eeooooooz si 8 290000000 m mm 5 5 m 2 280 4192 520 5 88 5409 882 amp amp 5 2 072 lt 02 R 0000000000000000 6600000000000 5666060000 8 5660560000 Cm 56606006000 sn 5666600606 266000000 Foo000000 zim m E Bd 800000000 9 566666666 simm 866060606000 3 606666666 8
4. ON i i435 RO 3452050 5 5 A 90959 0090509 090 666060668 66600000 566000000 5 5 56660606006 100000000 66666660 300000000 566600066 2066060060606 5 266600000 2000000000 500000000 566666600 100000000 5 5666660060 die 866600000 560666606006 8 5 366600000 5606006600606 zoe 2666606000 2666060006 00000000 260000000 6666666400069909 6066606640090556 0066660646000695 6666666600605650 6066660400009999 6660006600009999 6669600400009999 9990990999009959 24 S o x o O lt 1 lt 5 v 5 e la jo o A7 75 OHM TERMINATOR 320 INPUTS X 32 OUTPUTS Level 2 3 Bays DATA LINE LAN 1 FROM CPU 75 OHM TERMINATO
5. 704 INPUTS X 48 OUTPUTS Page 2 16 16 497 VIDEO INTERCONECT TO MONITOR CARDS VIDEO INTERCONECT TO MONITOR CARDS 866000000 860000900 2306600002 20 452 350 350 5 NG NG 2444 6646666 0000000004000 22 7900006000 8 096600606062 60000000 1999090009 z 660000060 Sn 566 1 600060000 Ss 566600000 1 566600000 660600000 500000000 Ss 966600000 z 5 566000000 S 3 60000000 6 566000000 566000000 560060000 266600066 5600600000 Sn 360060000 x L 3 566000000 S 3 566060000 ze _ 300000000 zim S 3 8006060000 500000000 8 1 560000006 566000000 860000600 560000000 S 000060 9 550 5146 0 2 330 6 6646666 666 ma 666 800000000 566060060600 2066660606 866006060060 2 866600000 206000000205 8660600000 566600606060 2000000006 800000000 16 16 2066660606 56000000025 16 2666660606 6666
6. 15 5 OL VILYA E 26 pO lov log DAD Toes 8211 10111118 lel 7 09 05 09 D Ir 021 io ano 100 1100 1100 1100 s sr st b A e 3 Ve 9 19 INI so 16 LOHNOOWILENI O3GIA SAW LOHNOOWILENI O3GIA 91 9 80 bO Co 2 LT 26 09 05 99 OVA 59 ano 20 110 1100 1100 1100 se E Hm e nt mt nt 2 2 e Nas H Are r9 re o QAF re re re N offe ANIT VLVG S 94 gt H e Ie o Of ne pe me 128 lt lt 665 696 ses 109 419 89 659 99 189 269 125 BB SAE VEVO
7. cocoon KIO Oro ID DIP Switch 54 Function RS 232 RS 422 RS 485 ole oW cool 2 1 0 0 Tj Front Panel LED s ON Front Panel LED s OFF 1 5 Video Input Module Switches Table 3 S1 Camera and Monitor Identification The 2016AVIM Video Input Module performs the actual 1 On O Off X Dont video switch Each module can switch any one of 16 video inputs to any video output or multiple combinations of video Switch Positions outputs up to 16 12345678 The 2016A Video Input Module must be set to the cameras and 1 16 X X X X X X monitors it is to respond to There are two 8 position dip 17 32 0 1 X X X X X X switches DIP switch S1 is used to set all field configurations 33 48 1 0 X X X X X X 49 64 11 X X X X X X The eight position dip switch S1 located on the circuit board 65 80 SE ONE CE E 81 96 0 1 X X X X X X must be set to identify the camera and monitor group The first 97 112 10 X X X X X X two switches select one of four groups of
8. 00000000000000000 06600600000000000 566000600600000600 10000000000000000 40000000000000000 60600000000000000 50000000000000000 9 999099999999 241 0606666666666666 69000000000000000 000000000000009 16 9000000000000000 AD2010R 257 120 VAC 50 60 Hz T DATA LINE SYNC 2 0 99 0000000000000 5 10000000000000000 6600000000000000 86600000000000000 0600000000000000 5600060000600000000 500000000 0 0000000 10000000000000000 00000000000000000 433 90000000000000900 9999999999909999 70000000000000000 00 05 AD2010R 000000009000 666900009 1 16 704 INPUTS X 16 OUTPUTS Page 1 Level 1 3 Bays DATA LINE 1 FROM VIDEO INTERCONNECT FROM CAMERA 5 513 SYNC 120 VAC 50 60 Hz 2 lt 54 lt a AR man lt 20 2 6666096660669606 56000000000600000 5600060000600000000 506660600000000000 100000
9. lt S oo o o o o o o o NVW of of o o o o o o o o o o Lo Oo E 215 625 195 ZZS 6S 609 529 199 459 9 689 SOL IZZ LEZ 9r EIS 54 SAVE WOU LOANODWALNI O1GIA o T INIT V LVG OT T 9524 5114110 8v X S LNANI 892 768 INPUTS X 48 OUTPUTS Page 2 Level 3 10 Bays VIDEO INTERCONECT TO MONITOR CARDS 34 53 0 2482 380 5 ise 50 lt 06 lt 335 85 5 be
10. 560000000 23 56 500000000 80990000 THE 220 220 3 50 5 2 52 5 E e Emuh 02 lt 2 0 02 9 999999909099999 6666666666666666 6666000000000000 560600000 mE 22422232 m 5606006000 5 z 560000000 5 8eeeooooo 800000000 Sc 3 00000000 100000000 866660666 FESS 100000000 50000009 100000000 Ss 566000000 2666060606 Sc 3 Foo000000 8 z i 5566600000 200000000 00660000 7606000000 sn 5060000000 860000000 5 5000000 E 66dooocbooco DATA LINE LAN 1 FROM CPU bdo00000000006 6660060006000909 4 990009595 9666600000060066 555 0009000999 9 999990000595 94 99099 09955 99999099000999 44 009 0008955 ddddoooclooo0dddd 5 4 co 14 lt WHO SZ
11. 560006000000000000 10000000000000000 560600060000000000 10000000000000000 6666666666666966 10000000000000000 10000000000000000 10000000000000000 10000000000000000 10000000000000000 100 10000000000000000 660000000006000000 0000000000000000 T 60900000000000000 DATA LINE TO BAYS 960 INPUTS X 16 OUTPUTS Page 1 Level 1 4 Bays DATA LINE LAN 1 FROM CPU 769 VIDEO INTERCONNECT FROM CAMERA BAYS 513 16 753 120 VAC 50 60 Hz TA LINE GN SYNC 5 666 90000000 56600060000000000 5600000600000000000 566606000000000000 6066000000000000 50006660000000000 10000000000000000 20000000000000000 399999 6600000000000000 660000600006000000 6600000000000000 606060000000000000 5660660000060000000 10000000000000000 6606006000000000 120 50 60 Hz 5 LINE 2 25 eoo lt 6000000000000000 945 9606666666666666 5 169 006666
12. o2 INPUT BAY 257 512 2010DB 2X 1 9 INPUT BAY 512 768 2010DB 3X Lo 140 4 L TKO 1 o 4 22 OH O 5 1 e 8 O 8 4 1 0 U 4 OUTPUT 1 4 2024VOM 1 Video Interconnections Page 2 Input Bays to Video Output Modules Outputs 125 128 gt o e 5 el e He 1 Le 158 28 e e o 158 28 28 e led ex 0 Gy 2 INPUT BAY INPUT BAY INPUT BAY OUTPUT 1 256 257 512 512 768 125 128 2010DB 1X 2010DB 2X 2010DB 3X 2024VOM 1 DECLARATION OF CONFORMITY According to ISO IEC Guide 22 and EN45014 Manufacturer s Name Sensormatic Electronics Corporation Manufacturer s Address 1 Blue Hill Plaza 2 Floor Pearl River New York 10965 USA Declares that the product listed below Name Type MegaPower Matrix Switching System Model Number ADS1024X all versions consisting of Name Type Bays Model Numbers AD2010R 1 AD2020R 1 Modules Model Numbers AD
13. 24 225 209 193 177 161 145 129 113 97 81 65 49 33 17 1 o o 1 o oo o o oo o o o o o lt o lt lt lt lt DATALNE GO oo o o 2 2 o o o o o o o o o o o OUT 9 o oo o o o o 2 lt lt lt lt lt o o 9 0 0 o lt lt 6 o o lt lt 6 20108 15 0000 Od D 1 2 20 4 D Video 8 Detection alarm output from 2010DBVL module Connection shown where distance between 2010 Bay and AD1024 CPU is over 7 feet and alarm output from 2010DBVL is provided to 2096 Alarm Interface Unit A19 2010DBVL to AD1981 Port Expander to AD1024 CPU Up to four 2010DBVL Modules
14. z 5000600000 jih 4000606000 100000000 3006606000 9000006000 S 3 896666666 z 3 860000006 S 3 366666666 Ae 2666606666 I 306666006 ZM mtn o aS 0660696699 6666666000000001 909099999 0009559 6000 0000 666000d0000 000 6606009600 5900606600009905 al S 5 10 75 TERMINATOR 54 8 beo 88 090000000000 06 5004000 700000000 5 gg 500000000 Sn 866006006 700000000 8 5 600006906 60000000 O00000 ae 560006000 Sn 66660660 560000000 26600
15. 2999999999999999 9999999990909099099 2010 15 Connection shown where distances between 2010 Chassis and AD1024 CPU is under 7 feet A18 256 INPUTS X 15 OUTPUTS With Video Loss Detection and Alarm Outputs Level 1 1 Bay ALARMO ey e x SELECT 12 3 4 5 6 7 8 9 101112 13 14 15 16 17 18 19 20 21 22 23 24 ATATATATATAT A A A A A A A A A A A A A A A A A A ABCDEFGH 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 241 Alarm Contact Alarm Ground ABCDEFGH ALATAS ATASAT L 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 1532 55 44 M AE AZAD ASAD AE LASAS ASAS AS R INPUT UT A AS A At A A A A 2096 AIU LINE PORTS PROG MON DO NOT CON JECT TELEPHONE 4 RUCITS 120V 60Hz E3 E3E ono Soa 1 2 1 2 4 4 5 6 7 8 9 10 AD1024 CPU
16. 60606000000000000 26000000000000000 0060666666666666 209000000000000000 299999909 ro09009009000000000000 50000000000000000 20900000000000000 0066666666666666 9666666666666606 241 2 1 2010 16 192 INPUTS X 16 OUTPUTS Level 1 1 Bay DATA LINE LAN 1 FROM CPU SYNC 120 VAC 50 60 Hz 2 LINE 23 6606606600660066000000 1900000000000000 3 66006600000000000 9 6060000000000000 0006666666666666 0666666666666666 10000000000000000 177 40000000000000000 429999999999009999 52999900909099990999 0000000000000000 000000000000 AD2010R 000000000000 000000006669 96066666602969 0000 16 A2 448 INPUTS X 16 OUTPUTS Level 1 2 Bays DATA LINE LAN 1 FROM CPU 1 120 50 60 Hz e OUT SYNC 6660666006000 0666666666666666 6666666666666066
17. 2 modules of bay 9 for video outputs 17 32 matching icon to icon lt gt Connect the top most BNC from bay 2 on the 2010DB 21 panel numbered 1 to the 2024VOM 2 in bay 9 for output 1 matching icon to icon gt Continue in this manner until connections 1 4 of the 2010DB 21 panel are connected to inputs 1 4 of the 2024VOM 2 Proceed to the next group of four on the 2010DB 21 and connect these to the second 2024VOM 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 21 panel are connected to the 2024VOM 2 modules for outputs 1 16 Connect bay 6 in a similar manner to the 2024 2 modules of bay 9 for video outputs 17 32 matching icon to icon Connect the topmost from bay 3 on the 2010DB 31 panel numbered 1 to the 2024VOM 2 in bay 9 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 31 panel are connected to inputs 1 4 of the 2024 2 Proceed to the next group of four on the 2010DB 31 and connect these to the second 2024 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 31 panel are connected to the 2024 2 modules for outputs 1 16 Connect bay 7 in a similar manner to the 2024 2 modules of bay 9 for video outputs 17 32 matching icon to icon Connect the top most from bay 4 the 2010DB 41 panel numbered 1 to the 2024VOM 2 in bay 9 f
18. 3 2 2 Emak mxm XZue Ooz 6666666666666666 6666666666660666 66000900 6060000 100000000 E 660060060060 S 3 28 60000000 Feeoooooo 28 900000000 S 566000600 200000000 S 3 Fooooo000 s amp 3 266666666 8566000000 506600000 SB 299600006 2 3666060000 S 3 856000000 Booooo000 Emm 566000000 zim 100000000 Sn 5666000600 500000000 sn 00000000 56060600000 5 E 5 mt wv 5 9999999999999999 9999999999008998 66000000000009999 coodooodooooddoo 60090009 660000000000066600 660000000000 000 66646666 OND 6606000000000 5 999 66060 00000000 090 606090009 5 24 2 amp amp m e amp IE 2 m lt lt lt lt a Mo e mj Y A12 AD2010R 75 OHM TERMINATOR AD2010R 241 256 INPUTS X 48 OUTPUTS Level 3
19. The lightning flash with arrowhead symbol within an equilateral triangle is intended to alert the RISK OF ELECTRIC SHOCK user to the presence of uninsulated DO NOT OPEN dangerous voltage within the product s enclosure that may be of sufficient magnitude to constitute a CAUTION TO REDUCE THE RISK OF ELECTRIC SHOCK risk of electric shock to persons COVERS NOR BACK The exclamation point within an NO USER SERVICEABLE PARTS INSIDE equilateral triangle is intended to alert the user to the presence of REFER SERVICING TO QUALIFIED SERVICE PERSONNEL important operating and maintenance servicing instructions in the literature accompanying the product WARNING UNPACKING AND INSPECTION Unpack carefully This is an electronic product and should be handled as such Compare the items received with the packing list with your order To reduce the risk of fire or shock hazard do not expose this product to rain or moisture Be sure to save This equipment has been tested and 1 The shipping cartons and insert pieces They are the safest material in which to make future shipments of found to comply with Part 15 of the the product FCC Rules 2 The IMPORTANT SAFEGUARDS sheet 3 These Installation and Operating Instructions Operation is subject to the following two conditions 1 This MAINTENANCE device may not cause harmful user maintenance of this unit is limited to external
20. From the rear of bay seven the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 32 with 16 for connection to the 2024VOM 1 modules in bay eight followed by sixteen 2016AVIM 3 modules inputs 513 768 32 From the rear of bay eight the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 3 modules inputs 769 960 and four 2024VOM 1 modules for outputs 17 32 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 2 192 X 32 Two Bay System and connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 bay 2 bay 3 and bay 5 bay 6 and bay 7 located on the rear panel of the 2010DB 11 2010DB 12 gt 20100 21 2010DB 22 201008 31 and 2010DB 32 ik are grouped by fours and identified by their icons Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four is used for video output connections See Figure 21 Video Output Module page 9 Using high grade RG 59U video cables connect the top most BNC from bay 1 on the 2010DR 11 panel numbered 1 to the top most input BNC labeled 1 for the
21. The 2024MDT front panel controls the brightness vertical and horizontal position for each title displayed on each of the four video outputs The 4 position rotary switch governs which output is selected for control The LED blinks to verify proper operation of the 2024MDT The front panel controls operate identical to those on the 2024VOM module see Figure 20 on page 9 Further details on operation of these controls is provided in the Video Output Module SETUP description page 17 Rear Panels The 2024MDT rear panel shown in Figure 23 has 12 BNC connectors and handles four separate video input channels A B C and D The bottom four BNC s are video outputs which contain time and date information from the system Data Line interface The upper four groups of BNC s are for video inputs from matrix switching bays and looping outputs to other video equipment such as VCR s Each BNC pair in the upper groups is an unterminated looping connection Video inputs to the 20204MDT module may be connected to either of the input pair of BNC s for each input channel If the video is terminated in the 2024 module and not looped to additional equipment via the paired BNC a 75 ohm terminating cap must be connected to the paired input BNC 75 ohm terminating caps are supplied for the looping BNC connectors If any video input is looped to another video device ensure that the line is terminated properly in 75 ohms The video output connections f
22. 1 366660000 8 7 566660606006 26666006 S 3 806660660 229009906 zim 23 856660606 3600000000 Sn 30000000 300000000 5666000006 256666006 100000000 gm 666660066009 600000000008 b oooo00000990 6600000005000 bo00d00000000 bdooodoooodddd 66466006666 6660 6deoocoooob o o v Teale lo 9 704 INPUTS X 32 OUTPUTS Page 1 Level 2 6 Bays 513 VIDEO INTERCONNECT FROM CAMERA BAYS DATA LINE LAN 1 FROM CPU 25 VIDEO INTERCONNECT FROM CAMERA BAYS DATA LINE TO BAYS 689 E in N 5 TEE 220 580 5 5 lt lt a a 2 0 lt lt 7 2 6666606666660066 0000000000000000 260000000 S 50 600 m 500000000 8 5 8600006000 366000000 Sn 100600000 S 300060000 8 5 250006006 566600000 8 5 8006060600 266000006 sn 66006666 66060606000 8 5
23. 512 X 48 Seven Bay System 39 Level 3 704 X 48 Nine Bay System 40 Level 3 768 X 48 Ten Bay 42 Level 3 960 X 48 Twelve Bay System 44 Level 3 1024 X 48 Fourteen Bay System 46 ADULP Looping Patel nieto eoo debe aa 48 Appendix Level 1 Interconnect Drawings eene Al 5 Level 2 Interconnect Drawings A6 All Level 3 Interconnect Drawings sees A12 A16 Level 8 Interconnect Drawings tene tiran A17 Video Loss Detector A18 A21 Video Buffer 22 GENERAL DESCRIPTION GENERAL DESCRIPTION The MegaPower II AD1024 Switcher Control System is integrated matrix switching and control system for CCTV surveillance systems It is capable of controlling up to 1024 video input sources such as cameras and 128 video outputs such as monitors and video tape recorders The AD1024 system consists of a matrix switching bay its power supply module a data receiver buffer module the required video input modules VIM video output modules and appropriate rear panels All AD1024 systems are controlled with a separate central processing unit CPU and keyboard AD1024 Switcher Control
24. 00000000 1 2 1 O gt 1 1 3 3 q ad Figure 12 2010DBVL 11 10 18 Multiple Bay System for cameras 1 256 Figure 13 2010DBVL 21 to 28 Multiple Bay System for cameras 257 512 SYSTEM MODULES DESCRIPTION All American Dynamics equipment is configured as RS 232 DTE Data Terminal Equipment devices For DTE to DTE connection to the 2010DBVL Terminal the XMIT pin of the 1996 port is connected to RCD pin 4 of the 2010DB VL Terminal Box the RCD pin of the 1996 port is connected to XMIT pin 5 of the 2010DB VL Terminal Box the Ground of the 1996 port is connected to GND pin 7 of the 2010DBVL Terminal Box Pins 1 and 2 provide a logic level alarm closure in accordance with the Alarm Contact mode set for the module see page 13 These pins are connected to the alarm contact inputs of a 2096 Alarm Interface Unit pin 1 to input and pin 2 to ground Where multiple 2010DBVL modules are used 1981 or 2081 port expanders are used to connect these modules to the AD1024 CPU The 2010DBVL 1x module must be connected to port A of the 1981 2010DBVL 2x to port B 2010DBVL 3x to port and 2010DBVL 4x to port D Video loss detection will not operate unless all modules are connected to the AD1024 CPU Typical connections of the 2010DBVL module are illustrated in the Appendix Figures A18 to A21 Ox 4 4 O
25. 4 Bays 06066666606666 E Roos 66600600000000 9000 666 0000000 0000 660060000000 000000000000 660600000890 6660000000000900 DATA LINE LAN 1 FROM CPU E 6660600000000 0000 649600000066 600000000000 6660000000900 dleoooooooooo0 6 a 6 due lt mj fe z 8 lt 2 lt 8 7 dhodo 346484665664 5950860 90000009 5 booooooosz 8 O00000 0 O z mimm 200000000 6 8 1 s06666666 sn 5 OOO 8s 200000000 8 1 00000000 20000000 8 1 5660600000 5 200000000 7 PPPOE m 5666060606060 300000 0O 2600060000 bee 6666660062 68 200000000 i 2660666662335 00000000 Ss 1 266000000 ami amp 8 1 00006006 000009 18 1 00000000 100000000 81 amp 8 8 2 u 2 E E 2 20 2 lt 0066666666666666 N 5 N 47 Y 1 0000 A13
26. In the Appendix see Figure A3 448 X 16 Two Bay System LEVEL 1 448 X 16 Two Bay System with Video Loss Detection A two bay Level 1 system with video loss detection allows a maximum of 448 video inputs switched to a maximum of 15 video outputs This system is the same configuration of modules as the LEVEL 1 448 X 16 system above except that the 2010DBVL 11 module is installed in place of the 2010DB 11 module in bay one and the 2010DBVL 00 module is installed in place of the 2010DB 00 module in bay two The connections are as described for the above system configuration except that only 15 are provided for video outputs Since two 2010DBVL modules are used this configuration requires the use of the 1981 Port Expander for connection to the ADAD1024 CPU See Appendix Figure A21 256 X 15 Two Bay System with Video Loss Detection Module LEVEL 1 704 X 16 Three Bay System A three bay Level 1 system allows a maximum of 704 video inputs switched to a maximum 16 video outputs Bays one and two consist of 256 video inputs and bay three consists of 192 video inputs and 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024 1 modules in bay three followed by sixteen 2016AVIM 1 modules for inputs 1 256 From the rear of bay two the modules are
27. Proceed to the next group of four BNCs on the 2010DB 11 of the first bay Connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to all of the 2024 1 modules 23 SYSTEM CONFIGURATIONS Connect bay 2 in a similar manner to the 2024VOM 1 modules of bay 3 for video outputs 1 16 matching icon to icon See Appendix Figure 18 Video Interconnections for illustration of these connections If there are less than four 2024VOM 1s in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See Level 1 448 X 16 Two Bay System and connect in a similar manner Video Output Connections See Level 1 448 X 16 Two Bay System and connect in a similar manner In the Appendix see Figure A4 704 X 16 Three Bay System SYSTEM CONFIGURATIONS LEVEL 1 960 X 16 Four Bay System A four bay Level 1 system allows a maximum of 960 video inputs switched to a maximum 16 video outputs Bays one two and three each consist of 256 video inputs Bay four consists of 192 video inputs and 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024VOM 1 modules in bay four followed by sixteen 2016AVIM 1 modules inputs 1 256 From the
28. The connections are as described for that system configuration except that only 15 are provided for video outputs See Appendix Figure A18 256 X 15 One Bay System with Video Loss Detection Module 21 SYSTEM CONFIGURATIONS LEVEL 1 192 X 16 One Bay System A one bay Level 1 system with 2024VOM modules for video titles allows a maximum of 192 video inputs switched to a maximum of 16 video outputs From the rear of the bay the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 1 modules and four 2024VOM 1 modules Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect Connect a 75 ohm coaxial cable from the DATALINE 1 output on the AD1024 CPU to the DATA IN BNC on the 2010PS rear panel Connect a 75 ohm BNC terminator supplied with the CPU to the Data Out BNC on the Power Supply rear panel Video Input Connections The 2016AVIM is identified with the video input icon The starting video input number for the particular VIM is located at the top BNC Each 2016AVIM 1 includes 16 terminated BNCs for video input connections The first 2016AVIM 1 located immediately to the left of the 2010DB 00 is for video inputs 1 16 the second 2016AVIM 1 module is for inputs 17 32 etc In su
29. a 257 512 1 16 not have to be set If S2 is set to OFF only specified 513 768 1 16 XX01 X00X information passes and S3 must be set The S3 switch allows 769 1024 1 16 XX11 X00 X only the necessary information to pass for that particular bay 1 256 17 32 XX 00 In the Condensed Bay configuration or when a bay ces 22 23 24 ins 2024VOM monitor modules the filter is set such 2 769 1024 17 32 XO 4g 4X X18 X that all information passes Therefore position 1 of switch S2 is set to ON 1 256 33 48 XX00X0 1X 257 512 33 48 XX 10X0 1X For all other configurations the filter is set such that 2 2248 Ms lt 769 1024 33 48 XX 11 X0 1X information is filtered thus position 1 of switch S2 is set to OFF and S3 must be set accordingly This applies to bays 1 256 49 64 XX00 X11xX which contain only 2016 VIM camera modules 257 512 49 64 0 513 768 49 64 769 1024 49 64 XX 11 X1 1X The Data Buffer Module also has a 2 position slide switch S1 S1 switches the card into either a normal mode or test mode 51 should be kept at the normal position Figure 25 shows the location of these switches on the 2010DB PCB card 841 111 Figure 25 Data Switches 12 Video Loss Detector Data Buffer Module Switches The 2010DBVL Video Loss Detector Data Buffer Mo
30. pushbutton The title steps through each level until the pushbutton is released The video output rotary switch may be placed to any position when title adjustment is completed 5 Power Supply Set Up Vertical Phase Adjustment The matrix switching bays are designed as vertical interval switches thus giving the matrix switching bay the ability to switch between properly phased video inputs without producing a vertical roll or a black bar between each video switch Use of this feature allows vertical interval switching to be controlled by the AC Line Line Locked External Vertical Drive Generator Locked or Composite video input 1 AC LINE The most common form of synchronization is AC line lock of the vertical switching point To use this feature switch the Sync Reference Selection switch to AC LINE see Figure 1 on page 2 This will use the AC either 60 or 50 Hz line to determine the vertical timing If all video inputs use the same phase of AC power to determine the vertical timing no roll will appear As an aid to the installer a switch on the Power Supply Module is available to check the vertical switch location for each video input This function is initiated when the SET UP NORMAL switch is selected to the SET UP position A Connect a monitor to the top most BNC of the 2010DB 00 labeled Test Expansion Only or the first monitor output of any level VOM If the monitor card is present connect to the video
31. 00 1100 100 100 1100 1110 100 NI NI NI NI NI NI NI NI NI NI NI NI NI NI NI NI onas 6 mo e INIT MIWA p 9r O ZH 09 0 OVA OZT 29 lind lno ino 1100 NI NI NI NI NI NI NI NI NI NI NI NI NI NI NI NI ouis S QA el oo e e S off 1 1 8r Lv lt o oo o oo 6 9 SO o LL 125 166 56 69S 585 109 119 9 679 S99 189 469 621 574 194 IZS 7 se 0 e ke 0 lox CD O 6 er ZH 09 05 0 p m o ns OVA OVAOZI 16 sy m 600 ez 179 1100 1120 LNO 1100 00 gt Le re 49 gt o olo eloelo To e o o o o o o o o o Gi o o o 7 9
32. 1 8 Monitors 5 8 ES si n Monitors 9 D ELI Monitors 13 164 Figure 28 Switches 16 The bay configuration switch was implemented on Rev Before Rev boards resistors were placed on the solder side of the board Condensed Bays only The 8 position DIP switch S2 located on the circuit board must be set to identify the video inputs and outputs the module must respond to Switch settings are dependent on the slot location in the matrix bay as well as which matrix bay the card is located Switch settings are shown in Tables 4a 4b and 5 Table 4 represents the first four switches of S2 which identifies video input If the video output is located in a matrix switching bay that includes video input cards its video input would be considered internal If the video output card is located in a matrix switching bay which contained only output cards its video inputs would be considered external Table 5 on page 17 identifies which video outputs the card will be controlling Table 4a S2 Internal Video Input Identification 1 On O Off Switch Positions Video Inputs 1 2 3 4 1 to 256 0 0 0 0 257 to 512 1 0 0 0 513 to 768 0 1 0 0 769 to 1024 0 0 1 0 Table 4b S2 External Video Input Identification 1 On O Off Switch Positions Video Inputs 1 2 3 4 1 to 256 1 0 0 0 257 to 512 0 1 0 0 513 to 768 0 0 1 0 769 to 1024 0 0 0 1 Note Table 4a
33. 2024VOM 1 in bay 4 for output 1 matching icon to icon lt gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 1 Proceed to the next group of four on the 2010DB 11 of the first bay and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to all of the 2024VOM 1 modules Connect bay 2 in a similar manner to the 2024VOM 1 modules of bay 4 for video outputs 1 16 matching icon to icon Connect bay 3 in a similar manner to the 2024VOM 1 modules of bay 4 for video outputs1 16 matching icon to icon Connect bay 5 in a similar manner to the 2024VOM 1 modules of bay 8 for video outputs 17 32 matching icon to icon lt gt gt Connect bay 6 in a similar manner to the 2024VOM 1 modules of bay 8 for video outputs 17 32 matching icon to icon Connect bay 7 in a similar manner to the 2024VOM 1 modules of bay 8 for video outputs 17 32 matching icon to icon See Appendix Figure 18 Video Interconnections for illustration of these connections If there are less than eight 2024VOMs in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 2 192 X 32 Two Bay System and connect in a similar manner Video Output Connections See LEVEL 2 192 X 32 Two Bay System and connect in a similar man
34. 32 matching icon to icon gt gt Connect bay 6 in a similar manner to the 2024VOM 1s of bay 7 for video outputs 33 48 matching icon to icon lt gt See Appendix Figure A18 Video Interconnections for illustration of these connections If there are less than twelve 2024VOM 1s in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner Video Output Connections video outputs are located in bay 7 See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner SYSTEM CONFIGURATIONS LEVEL 3 704 X 48 Nine Bay System A nine bay Level 3 system allows a maximum of 704 video inputs switched to a maximum 48 video outputs Bays one two four five seven and eight consists of 256 video inputs each Bay three consists of 192 video inputs with the first group of 16 video outputs Bay six consists of 192 video inputs with the second group 16 video outputs Bay nine consists of 192 video inputs with the third group 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024VOM 1 modules in bay three followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following mann
35. BNCs for connection to 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 4 modules inputs 1 256 40 From the rear of bay eight the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 23 with 16 BNCs for connection to the 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 4 modules inputs 257 512 From the rear of bay nine the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 4 modules inputs 513 704 and four 2024VOM 1 modules outputs 33 48 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 3 192 X 48 three bay system and connect all bays in a similar manner Video Interconnections The 16 video outputs from bays 1 2 4 5 7 and 8 located on the rear panel of the 2010DB 11 12 13 and 21 22 and 23 2 respectively grouped by fours and identified by their icon s Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four BNCs is used for video output connections The left most 2024VOM 1 module is assigned to outputs 1 4 the next for outputs 5 8 etc See Figure 21 Video Output Module page 9 Us
36. Loss Detector Data Butter 13 Video Input dut etin ia iue 14 Video 16 Power Supply 18 Powering Up Powering the Matrix nane naa et 19 CONTENTS Page System Configurations Level 1 Systems Level 1 256 X 16 One Bay with No Titles 20 Level 1 192 X 16 One Bay System 21 Level 1 448 X 16 Two Bay 22 Level 1 704 X 16 Three Bay 23 Level 1 960 X 16 Four Bay System 24 Level 1 1024 X 16 Five Bay System 25 Level 2 Systems Level 2 04 X 32 One Bay System uere teras 27 Level 2 192 X 32 Two Bay 5 28 Level 2 320 X 32 Three Bay System eerte 29 Level 2 448 X 32 Four Bay System 30 Level 2 704 X 32 Six Bay System ceteros 31 Level 2 960 X 32 Eight Bay System 22 Level 2 1024 X 32 Nine Bay System 34 Level 3 Systems Level 3 192 X 48 Three Bay 36 Level 3 256 X 48 Four Bay System 37 Level 3 448 X 48 Six Bay 38 Level 3
37. NOT ONO TENT OION SAW WOW LOHNOOWILLINI O1GIA 4 m gO O 2 09 05 0 z 021 19 lino ino Jano ino eO sO S Yo o 9 orere rere we fo INIT lt lt Ol lt 9 A Em d 9 o oo o o9 lt Ime INOW NVT INIT V LVG SAVE WOU 1 SAVE WOU 1 IS A 689 sAeg 6 9491 5 8 X SLNdNI Level 3 9 257
38. Systems are supplied as completely configured switching bays Only the bay interconnections the CPU connections the video input and output connections and any optional accessory connections need be made prior to operation The AD1024 system as delivered is a complete system with all inputs terminated in 75 ohms Each bay is packed in a separate shipping carton labeled with the AD1024 bay assembly number on the outside of the carton Matrix Switching Bay The 2010R and 2020R switching bays include the physical chassis a back plane a power supply module and a data receiver Each bay has the capability of looping the DATA LINE input and looping an external vertical synchronization pulse to other bays Each bay also accommodates a combination of video input modules and video output modules up to a total of 16 modules Power 50 watts full system Size 10 1 2 height Full width 19 rack mount Weight 60 165 28 kg full system CPU Central Processing Unit The CPU for the AD1024 system is a separate rack mounted unit that includes its own power supply system software ten RS 232 ports a system diagnostic monitor output and two DATA LINE outputs These DATA LINE outputs distribute high speed data control signals to the AD1024 matrix switching bays and optional accessories AD1024 Central Processing Unit Power 4 watts Size 1 75 height Full width 19 rack mount Weight 10 165 4 5 kg OPTIONAL EQUIPMENT The follo
39. by qualified service personnel and should conform to all local codes Safeguards must be taken to avoid unintentional operation by employees and maintenance personnel working about the premises by falling objects by customers by building vibration and by similar causes SYSTEM MODULES DESCRIPTION SYSTEM MODULES The following pages describe the plug in modules available for AD1024 switching bays These include Power Supply Module 2010PS Data Buffer Module 2010DB Video Loss Detection Data Buffer Module 2010DBVL Video Input Module 2016AVIM Video Output Module 2024 Master Date Time Module 2024MDT Power Supply Module 2010PS The power supply module for the matrix switching bay converts AC power to the necessary DC voltages which are supplied to all the modules in the switching bay Front Panel Figure 1 illustrates the features described below 1 SYNC TEST ON OFF LED This red LED is illuminated when the SET UP NORMAL switch below is in the SET UP position 2 SET UP NORMAL SWITCH When set to the SET UP position this switch implements sync test and adjustment See Power Supply Setup page 18 3 SYNC LOSS LED This red LED is off if video sync is locked When illuminated it indicates that sync is not locked due either to a poor sync signal no sync signal or the wrong sync signal as determined by the setting of the sync selection switch below 4 SYNC REFERENCE SELECTION SWITCH This switch se
40. factory in the following manner the far right module is the 2010PS the next module is the 2010DB 13 with 16 for connection to the 2024 1 modules in bay seven followed by sixteen 2016AVIM 4 modules inputs 1 256 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 23 with 16 for connection to the 2024 1 modules in bay seven followed by sixteen 2016AVIM 4 modules inputs 257 512 From the rear of bay seven the modules are installed at the factory in the following manner the far right module is the 2010 5 the next module is the 2010DB 00 followed by twelve 2024VOM 1 modules installed left to right for outputs 1 48 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 3 192 X 48 Three Bay System and connect all bays in a similar manner 39 SYSTEM CONFIGURATIONS Video Interconnections The 16 video outputs from bay 1 through 6 located on the rear panel of the 2010DB 11 12 13 21 22 and 23 gt respectively are grouped by fours and are identified by their icons Each 2024 1 is similarly grouped with three sections of four with identifying icons The left most 2024 1 module is assigned to outputs 1 4 the next fo
41. in the following manner the far right module is the 2010PS the next module is the 2010DB 23 with 16 for connection to the 2024 1 modules in bay ten followed by sixteen 2016AVIM 4 modules inputs 257 512 42 From the rear of bay nine the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 33 with 16 BNCs for connection to the 2024 1 modules in bay ten followed by sixteen 2016AVIM 4 modules inputs 513 768 From the rear of bay ten the modules are installed at the factory in the following manner the far right module is the 2010 5 the next module is the 2010DB 00 followed by twelve 2024VOM 1 modules installed left to right for outputs 1 48 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 3 192 X 48 Three Bay System and connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 through 9 located on the rear panel of the 2010DB 11 12 13 x 21 22 23 and on rear panels 31 32 and 33 x respectively They are grouped by fours and identified by their icons Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four BNCs is used for video output connections The left most 2024VOM
42. inputs switched to a maximum 16 video outputs Bays one through four each consists of 256 video inputs and bay five consists of the 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024 2 modules followed by sixteen 2016AVIM 1 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 for connection to the 2024 2 modules in bay five followed by sixteen 2016AVIM 1 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 31 with 16 BNCs for connection to the 2024 2 modules in bay five followed by sixteen 2016AVIM 1 modules inputs 513 768 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 41 with 16 for connection to the 2024VOM 2 modules in bay five followed by sixteen 2016AVIM 1 modules inputs 769 1024 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 follo
43. is used when the 2024VOM is located in a matrix switching bay which includes 2016AVIM Table 4b is used when the 2024VOM is located in a matrix switching bay which does not include 2016AVIM modules In both instances the Filter DIP switch S2 on the 2010DB 2010DB VL Data Buffer Module must be set to pass all data see page 12 DIP Switch S1 and slide Switch S3 are not used on the 2024VOM card Table 5 52 Video Output Identification Video Output 1104 5108 9 to 12 13 to 16 17 to 20 21 to 24 25 to 28 29 to 32 33 to 36 37 to 40 41 to 44 45 to 48 49 to 52 53 to 56 57 to 60 61 to 64 d d Ve 1 0 Switch Positions 5 6 1 8 0 0 0 0 1 0 0 0 0 1 0 0 1 1 0 0 0 0 1 0 1 0 1 0 0 1 1 0 1 1 1 0 0 0 0 1 1 0 0 1 0 1 0 1 1 1 0 1 0 0 1 1 1 0 1 1 0 1 1 1 1 1 1 1 a Blinking LED for proper operation 4 4 rotary switch A Horizontal control push button 4 Vertical control push button bas Brightness control push button Figure 29 Video Output Module Front Panel SETUP Video Output Module Horizontal Vertical and Brightness Adjustment The 2024VOM has four video outputs each with title information displayed on the video picture The title information on the screen is adjustable for horizontal and vertical position The brightness of the characters is also adjustable The rotary switch located on the front panel of each output module selects which ou
44. loop the EXT SYNC from input to output for all bays and terminate the last bay EXT SYNC OUT BNC in 75 ohms Monitor 1 alignment bar C C X o Figure 30 Placement of Setup Alignment Bar Alignment bar should be visible on the monitor and not in the vertical sync POWERING UP The system may be brought on line after The CPU has been installed and connected A video input has been connected A monitor has been connected for viewing the output lines have been properly terminated One keyboard or external computer has been connected for control Power has been connected to the equipment one bay at a time ending with the CPU Powering the Matrix Bay 1 Unscrew the two thumbscrews located at the top corners of front panel of each matrix switching bay 2 Remove the front panel by first slowly pulling the top of the panel towards the front then lifting the panel up Note DO NOT remove the foam material attached to the front panel 3 Verify that the unit is turned off The unit is turned off by pressing the bottom of the front panel power On Off switch 4 Power is supplied via a pendant cord and plug Connect the pendant cord to the required voltage input AD1024R 120VAC 50 60 Hz ADS1024RX 230VAC 50 60 Hz 5 To turn the unit on press the top of the front panel power On Off switch Replace the front panel only after all setup adjustments have been made related to poweri
45. may be connected to one AD1981 Port Expander 2010DBVL using 2010DBVL 5 the following AD1981 port assignments KBD a 2010DBVL 1x Cameras 1 256 KBD b 2010DBVL 2x Cameras 257 512 2 KBD c 2010DBVL 3x Cameras 513 768 KBD d 2010DBVL 4x Cameras 769 1024 A 2 i CONDUCTOR SHIELDED AD1 981 74 BELDEN 8770 OR EQUIVALENT DATA LINE PORTS 5 PROG DO CONNECT TO TELEPHO CIRCUITS 1 20V 1 2 1 2 3 4 5 6 7 8 9 10 AD1024 A20 448 INPUTS X 15 OUTPUTS With Video Loss Detection Level 1 2 Bays with AD1981 Port Expander PROG MON MM PORT DATA 00 TELEPHONE CIRCUITS E3 E3 FO 3 10 AD1024 CPU m 2 0 5 z 00 0009050000450 0066666669666690 60060000000000000 60060000000000000 6000000000000000 0000000000000000 0066666666666660 00666666666966 660 06666666696666 6660 6000000000000
46. mm F2 125V 5 AMP 5 x 20 mm F3 250V SB 0 5 AMP 5 x 20 mm UL listed F4 250V SB 0 5 AMP 5 x 20 mm UL listed For 230VAC CE Compliant Systems F1 250V T 3 15 5x 20mm F2 250V T 3 15 5x 20mm For 230VAC Non CE Compliant Systems 125V 5 AMP 5 20 F2 125V 5 AMP 5 20 F3 250V T 0 25 AMP 5 x20 mm F4 250V T 0 25 AMP 5 x 20 mm SYSTEM MODULES DESCRIPTION Power Supply Module Rear Panel Figure 2 is the illustration associated with the features described below 8 SERIAL TAG Serial number assigned to this AD1024 switching bay Model AD2010 9 DATA LINE IN Input for DATA LINE 8 S N XXXXX 10 DATA LINE OUT Looping output for DATA LINE This line must be terminated with a 75 ohm terminator 11 EXTERNAL SYNC IN Input for external vertical synchronous pulse either camera sync or an externally created sync pulse 12 EXTERNAL SYNC OUT Looping output for EXT SYNC This line must be terminated with a 75 ohm terminator gt DATA IN SYNCI 12 OUT Op 120 V 60 Hz Figure 2 Rear Panel of Power Supply Module SYSTEM MODULES DESCRIPTION Data Buffer Module 2010DB The Data Buffer Module serves a dual purpose First it distributes switched video from the bay s Video Input Modules to other bays in multiple bay systems The video observed
47. modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 31 with 16 BNCs for connection to the 2024 1 modules in bay ten followed by sixteen 2016AVIM 2 modules inputs 513 768 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 BNCs for connection to the 2024 1 modules in bay ten followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 22 with 16 BNCs for connection to the 2024VOM 1 modules in bay ten followed by sixteen 2016AVIM 3 modules inputs 257 512 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 32 with 16 BNCS for connection to the 2024 1 modules in bay ten followed by sixteen 2016AVIM 3 modules inputs 513 768 From the rear of bay seven the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 13 with 16 for connection to the 2024 1 modules in bay ten followed by sixteen 2016AVIM 4 modules inputs 1 256 From the rear of bay eight the modules are installed at the factory
48. next group of four on the 2010DB 21 and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 21 panel are connected to 2024VOM 1s for outputs 1 16 Connect bay 6 in a similar manner to the 2024VOM 1s of bay 8 for video outputs 17 32 matching icon to icon Connect bay 10 in a similar manner to the 2024VOM 1s of bay 12 for video outputs 33 48 matching icon to icon Connect the top most BNC from bay 3 on the 2010DB 31 panel numbered 1 to 2024 1 in bay 4 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 31 panel are connected to inputs 1 4 of the 2024VOM 1 Proceed to the next group of four BNCs on the 2010DB 31 and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 31 panel are connected to 2024VOM 1s for outputs 1 16 Connect bay 7 in a similar manner to the 2024VOM 1s of bay 8 for video outputs 17 32 matching icon to icon Connect bay 11 in a similar manner to the 2024 15 of bay 12 for video outputs 33 48 matching icon to icon See Appendix Figure A18 Video Interconnections for illustration of these connections If there are less than eight 2024VOM 1s in the system the remaining BNCs on the 2010DB XX do not require any connection 45 SYSTEM CONFIGURATIONS Video Input Connecti
49. next module is the 2010DB 00 followed by four 2024VOM 2 modules installed left to right outputs 33 48 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 3 192 X 48 three bay system and connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 through 12 located on the rear panel of the 2010DB 11 12 13 gt 2010DB 21 22 23 20100 31 32 33 and 2010DB 41 42 and 43 respectively They are grouped by fours and identified by their icons Each 2024 2 is similarly grouped with four sections of four BNCs with identifying icons A fifth group of four BNCs lower left hand corner is used for video output The left most 2024VOM 2 module is assigned to outputs 1 4 the next for outputs 5 8 etc See Figure 21 page 9 Using high grade RG 59U video cables connect the top most BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024VOM 2 in bay 13 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 2 Proceed to the next group of four BNCs on the 2010DB 11 and connect these to the second 2024VOM for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to 2024VOM 2
50. rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 for connection to the 2024VOM 1 modules in bay four followed by sixteen 2016AVIM 1 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 31 with 16 BNCs for connection to the 2024VOM 1 modules in bay four followed by sixteen 2016AVIM 1 modules inputs 513 768 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010 5 the next module is the 2010DB 00 followed by twelve 2016AVIM 1 modules for inputs 769 960 and four 2024VOM 1 modules for outputs 1 16 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See Level 1 448 X 16 Two Bay System and connect all bays in a similar manner Video Interconnections The 16 video outputs from bays 1 2 and 3 located on the rear panel of 2010DB 11 gt 20100 21 and 2010DB 31 it are grouped by fours and identified by the icons Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four BNCs is used for video output connection
51. sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 BNCs for connection to the 2024VOM 1 modules in bay four followed by sixteen 2016AVIM 2 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 31 with 16 BNCs for connection to the 2024 1 modules in bay four followed by sixteen 2016AVIM 2 modules inputs 513 768 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 2 modules inputs 769 960 and four 2024VOM 1 modules for outputs 1 16 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024 1 modules in bay eight followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 22 with 16 for connection to the 2024VOM 1 modules in bay eight followed by sixteen 2016AVIM 3 modules inputs 257 512
52. the 2010DB 11 with 16 BNCs for connection to the 2024 1 modules in bay two followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 2 modules inputs 257 448 and four 2024VOM 1 modules outputs 1 16 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the video output modules in bay four followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 3 modules inputs 257 448 and four 2024VOM 1 modules outputs 17 32 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 13 with 16 for connection to the video output modules in bay six followed by sixteen 2016AVIM 4 modules inputs 1 256 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 4 modules inputs 257 448 and four 2024
53. the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 BNCs for connection to the 2024 1 modules in bay four followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 13 with 16 BNCs for connection to the 2024 1 modules in bay four followed by sixteen 2016AVIM 4 modules inputs 1 256 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2024VOM 1 modules installed left to right for outputs 1 48 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 3 192 X 48 Three Bay System and connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 bay 2 and bay 3 located on the rear panel of the 2010DB 11 37 SYSTEM CONFIGURATIONS 12 and 13 respectively are grouped by fours and identified by the icon lt gt Each 2024 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four BNCs is used for video output connections The left mo
54. 00 50000000028 500000000 3 766000066 8 z 000000000 8 26000000 m PATA LINE TO BAYS 4 DATA LINE 1 FROM CPU DATA LINE 2 FROM CPU 75 OHM TERMINATOR Oe OUT lt IN wt OUT Oe OUT lt 000000 49 DATA LINE X A X P A N 5 1 N DATA LINE lt DATA LINE 8 AD2020R AD2020R AD2020R 700000008 100000006 200000008 000000009 75 OHM TERMINATOR OUT DATA LINE 75 OHM TERMINATORS AD2020R 606000000 000000009 000000009 64 INPUTS X 128 OUTPUTS Level 8 60660000 566000000 60600000 200000006 00000000 Ow Ors 000000009 Os Ou 000000009 Ore Ou 00000000 On Ou 17 90960609090606 06666666066606 066666660666
55. 000 60060000000000000 99999999 9 9 9909099 0000000000000000 241 0000000000000000 06600000000000000 60060000000000000 2010 DATA LINE 1 T i DATA LINE 0006600060966066 6000000000000000 6000000000000000 0000000000000000 0000000000000000 0000000000000000 6000000000000000 6000000000000000 6000000000000000 0000000000000000 0066666666666666 AD2010R 99960999 64 999999999 0000000900 e e5 468 Mi 00000 00000 o 9000 9000 9000 9000 C AD1981 A21 Video Interconnections Page 1 Input Bays to Video Output Modules Outputs 1 4 t en t gt 0000006000606060 t o INPUT BAY 1 256 2010DB 1X 1441 19 Ww gt
56. 000 800606060 A 860000000 S 3 266066066 266666606 90666600628 860000000 Sn 806060600 300000000 8 260000000 y 005 1145 6405299 6666 5555 566 99998535 5555 99999555 66 500 11 75 OHM TERMINATOR DATA LINE TO BAYS 960 INPUTS X 32 OUTPUTS PAGE 2 Level 2 8 Bays VIDEO INTERCONECT TO MONITOR CARDS 348 else 80 zio 35 cates _ gt 0099000000005006 5548564650438 60000000 8 90000000 m 60666666 8 5 8 6666606628 266060006 8 5 6606060002 amp 266060006 8 5 5 66666066 S 3 266060006 8 5 5 2606060000 sn 2 9660066628 56006060000 5 Beooooooo h6eeoooco Weeeeoooos 5 3 860000
57. 000 8 7 66006006 266060006 Sc 3 500060000 2 5 3600606000 Sn 6006000002 S5 _ 26666000628 300000000 206000600 8 566000000 8 00000000 a 5 zh S8 Sut it 209060600 6 100000000 8 e 566660000 S 3 860000000 860006000 260000006 296600600 8 7 300000000 500000000 Sn 8600000060 500000000 8 7 60066666 amem 260006000 8 866000000 s keeeeeeoes s 3 266606606 200600000 z 3 500000000 Sc 3 2666060006 760000000 200060006 266606606 8 1666666606 zim Di 9660606060060 8 300000000 060000000 amp 500000000 3 300000000 E 497 060600000 80000000 DATA LINE TO BAYS 75 OHM TERMINATOR Level 3 3 Bays 192 INPUTS X 48 OUTPUTS 2 E 5 od 1 5 oS 5 5 5 9
58. 00000000000 560000000000000000 10000000000000000 6006666666966666 300000600000000000 360000000060000000 10000000000000000 50000000000000000 00000000000000000 0606666666660666 5 99 4912 6006000000000 0066606666066969 96 O10 08 9660666666660666 rel OS 4 DATA LINE 5 16 704 INPUTS X 16 OUTPUTS Page 2 Level 1 3 Bays VIDEO INTERCONNECT TO MONITOR CARDS 16 241 LINE N 120 VAC 50 60 Hz C GA 5 66 99499669 re000000000000000 10000000000000000 10000000000000000 00000000000000000 00000000000000000 0066666666666666 56000000000000000 76066000000000000 56000000600000000 560000000066000000 56660000000000000 56660000000000000 566060000000000000 56000060000000000 56000060000000000 0600000000000000 257 16 497 N 120 VAC 50 60 Hz SYNC at LINE 9999994904449960
59. 0006 ae 560000000 Sn 66606006 zem 500000000 Sn 660060006 5606006000 Sn 56606060000 190000099 Sn 5 zamm 5000006000 Sn 5oo000000z c 23 8 cd 560000000 8 5 200000000 6 5 2 500000000 206006000028 E A 5000006000 8 0 8606060000 Om 506600000 3 30000000 500600000 5 1 gt 5 2 92 1411 fo 566 Ho 6 Er Ed oo e 366000000 E d60000002 560000000 3 560000000 860600000 8 5 5606006006 100000000 so 266000006 ae 500000000 Sn 50066006000 amp 5 100000000 Sn 200000000 zim 100000000 266600600028 N800000000 s Nkoo000000 200000006 8 500000000 8 7 200000000 amem 2 5 300000000 Sn 1 lt Seeeeeeee 8 8 4 2 8 200000000 2 8 gt 200000000 5 960 INPUTS X 32 OUTPUTS Page 1 Level 2 8 Bays
60. 006000000000600000 86660000000000000 80000000000000000 goooooooo00000000 50000000000000000 20000000000000000 20000000000000000 0666666666666966 6000000000000000 10000000000000000 10000000000000000 10000000000000000 20000000000000000 0000000000000000 IS 600000000000000 DATA LINE TO BAYS WHO 62 YOLVNINYAL WHO SZ LT cE NO 2 09 05 09 19 ing INIT VLYA S 600000000 zeal bao po Jor NI 2666666606 6666060990000666 660000000000 600000000000 660000000000 70000000 790000000 00000000 NI 9 5 0000000 NI 0000000 NI 000000006 6606000000009 6666660000686 6060000000006 666 96066666666660 INO NYT INIT V LVG Keg T 9421 X SL dNI 9 91 192 INPUTS X 32 OUTPUTS Level 2 2 Bays DATA LINE LAN 1 FROM CPU 75 OHM TERMINATOR
61. 024VOM modules for outputs 1 16 bay two for outputs 17 32 In the Appendix see Figure A7 192 X 32 Two Bay System LEVEL 2 320 X 32 Three Bay System A three bay Level 2 system allows a maximum of 320 video inputs switched to a maximum 32 video outputs Bay one consists of 256 video inputs for the first 16 video outputs and bay two consists of 256 video inputs for the second group of 16 video outputs Bay three a 2020R Condensed bay consists of 64 video inputs for both groups of outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024 1 modules in bay three followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024VOM 1 modules in bay three followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by four 2016AVIM 2 modules for inputs 257 320 and four 2024VOM 1 modules for outputs 17 to 32 The next modules to the left are four 2016AVIM 3 modules for inputs 257 320 followed by four 2024VOM 1 modules fo
62. 06 90666666606066 33 65 0000 49 17 81 64 80 16 32 48 96 113 97 112 128 256 INPUTS X 15 OUTPUTS With Video Loss Detection Level 1 1 Bay 120V 60Hz PROG MON PORTS DO NOT CONNECT TO TELEPHONE CIRCUITS E E E EBEGBGIEEGU E E DATA LINE AD1024 CPU DATA LINE 1 Video Loss Detection alarm output from 2010DBVL module e 120 50 60 Hz DATA LINE 000960099000 099 r 166060000000000000 241 760060000000000000 6060000606000000000 366060000000000000 900000060000000000 99000000000000000 s 6000006000000000 10000000000000000 9900999 9 999 0000000000000000 9900000000000000 L0909090909009090999999090 50000000000000000 89999999999999999
63. 0DB continued 1 a Output 8 Output 16 Figure 6 2010DB 21 to 2010DB 28 Rear Panel w 16 BNCs Multiple Bay System for cameras 257 512 O 1 Output 1 4 s or Or 8 Outputs 9 2 3 Ox OT 6 Output 16 Figure 7 2010DB 31 to 2010DB 38 Rear Panel w 16 BNCs Multiple Bay System for cameras 513 768 SYSTEM MODULES DESCRIPTION 1 M 8 aM 16 Figure 8 2010DB 41 to 2010DB 48 Rear Panel w 16 BNCs Multiple Bay System for cameras 769 1024 SYSTEM MODULES DESCRIPTION Video Loss Detection Data Buffer Module 2010DBVL The Video Loss Detector Data Buffer Module provides the same capabilities as the 2010DB Data Buffer Module with one significant addition First it distributes switched input video with no character information to multiple bay systems It also filters incoming information from the DATA LINE to allow for the passage of localized information The additional function of this module is to detect the presence of a video signal for each camera input Each module can detect video loss for a maximum of 256 cameras For a full matrix switching system of 1024 cameras four 2010DBVL modules are required one for each block of 256 cameras The 2010DB
64. 0DBVL for the desired communications rate DIP switch S3 must be set to the camera and monitor group numbers assigned to the switching bay modules 54 53 52 STE Figure 26 DBVL Data Buffer Card Switches SETUP DIP switch S4 sets the type of communication used via the RJ45 port and enables or disables the 2010DB VL front panel LED s This port may be configured for RS 232 RS 422 or RS 485 communications The following tables show the switch position settings for DIP switches S2 S3 and S4 Figure 26 shows the location of these DIP switches on the 2010DBVL card Table 2 S2 S3 and S4 switch settings 1 On 0 X Don t care DIP Switch 52 Function Video Loss Enabled Video Loss Disabled Pass information Pass only specified information Alarm during Video or Sync loss Alarm during loss plus 10 seconds Alarm at loss for 10 seconds Alarm at loss for 20 seconds Or 1200 Baud Rate 2400 Baud Rate 4800 Baud Rate 9600 Baud Rate o ocr o DIP Switch S3 Monitor 1 16 1 16 1 16 1 16 17 32 17 32 17 32 17 32 33 48 33 48 33 48 33 48 49 64 49 64 49 64 49 64 Camera 1 256 257 512 513 768 769 1024 1 256 257 512 513 768 769 1024 1 256 257 512 513 768 769 1024 1 256 257 512 513 768 769 1024 FOr olh
65. 1 module is assigned to outputs 1 4 the next for outputs 5 8 etc See Figure 21 page 9 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024 1 in bay 10 for output 1 matching icon to icon lt gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024VOM 1 Proceed to the next group of four on the 2010DB 11 of the first bay and connect these four to the second 2024VOM 1 of bay 10 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to the 2024VOM 1s for outputs 1 16 Connect bay 4 in a similar manner to the 2024VOM 1s of bay 10 for video outputs 17 32 matching icon to icon lt gt Connect bay 7 in a similar manner to the 2024VOM 1s of bay 10 for video outputs 33 48 matching icon to icon lt gt Connect the top most BNC from bay 2 on the 2010DB 21 panel numbered 1 to the 2024 1 in bay 10 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 12 panel are connected to inputs 1 4 of the 2024VOM 1 Proceed to the next group of four on the 2010DB 12 and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 21 panel are connected to the 2024 1 modules for outputs 1 16 Connect bay 5 in a similar
66. 16 monitors and the 113 128 last six select one of 64 groups of 16 cameras Switch settings are shown in Table 3 Camera The monitor group selection is independent of the camera group selection Yet both monitor and camera group must be 1 16 X WM EX selected correctly depending on the particular slot the card is AN Mb M E 33 48 X X 0 0 0 0 1 0 being placed in Note The silkscreen on the board clearly 49 64 X X 000 1 I shows the correct dip switch to use The word CAM GRP is screened adjacent to the correct dip switch 65 80 X X 0 0 0 1 0 0 81 96 X X 0 0 1 0 1 The DIP switch S3 is not used in this module Haz 113 128 X X 0 1 1 1 129 144 X X 1 0 0 0 145 160 X X 0 10 0 0 1 161 176 X X 10 0 177 192 X X 0 1 0 1 s ss Figure 27 Video Input Module Card Jumper Switches 14 5 Table 3 S1 Camera and Monitor Identification continued Switch Positions DI wl eni Al cooo X X x PAPA x 193 208 209 224 225 240 241 256 257 272 273 288 289 304 305 320 321 336 337 352 353 368 369 384 on gt lt oon cooo X X
67. 2010PS 1 Power Supply AD2016AVIM Video Input AD2024AVOM Video Output AD2010DB Data Buffer complies with all applicable directives as demonstrated by conformance to the following Product Specifications Safety EN 60950 1992 EMC EN 50130 4 1995 55022 1994 Class B EN 61000 3 2 1995 EN 61000 3 3 1995 EN 61000 4 2 1995 EN 61000 4 3 1996 EN 61000 4 4 1995 EN 61000 4 5 1995 EN 61000 4 6 1996 EN 61000 4 11 1994 Supplementary Information The products herewith comply with the requirements of the Low Voltage Directive 73 23 EEC as amended by 93 68 EEC and the EMC Directive 89 339 EEC as amended by 93 68 EEC Pearl River NY USA 1 October 2000 WE Harold D Johnson Ph D Director of Engineering European Contact Sensormatic France S A 7 rue Alexis de Tocqueville Parc de Haute Technologie 92183 ANTONY CEDEX SPECIFICATIONS Supply Voltage AD1024R 120 VAC 50 60 Hz 50 W ADS1024RX 230 VAC 50 60 Hz 0 50 A Temperature 09C 60 C 32 F 140 F Humidity Relative humidity between 0 and 95 non condensing Mounting Free standing or rack mount Size 19 W x 10 5 H x 18 5 D Rack 17 5 Desk Width Weight 55 Ibs Finish Black Sensormatic Video Systems Division One Blue Hill Plaza Pearl River New York 10965 845 624 7600 Technical Support Center 800 442 2225 FAX 845 624 7685 8000 1812 01 Revision A December 2000 Printed in USA
68. 5 5 5 8 Og oO 2 2 Figure 14 2010DBVL 31 to 38 Multiple Bay System for cameras 513 768 Figure 15 2010DBVL 41 to 48 Multiple Bay System for cameras 769 1024 SYSTEM MODULES DESCRIPTION Video Input Modules 2016AVIM The 2016AVIM performs the actual video switching in the AD1024 switching bay Each module can switch any one of 16 video inputs to any video output or multiple combinations of video outputs up to 16 The 16 video inputs to the module are connected at the rear panel associated with the video input module The switched video outputs are provided to the Video Output Modules and the Data Buffer Module in the bay There are four different types of rear panels shown below Icon Definition The following icon denotes video inputs 4 Input 1 EN ih Q Q 84 Input 8 8 9 1 2 1 3 1 U 1 6 4 Input 16 T Figure 16 Figure 17 2016AVIM 1 2016AVIM 2 The 2016AVIM 1 as seen in Figure 16 has 16 BNC connectors for video inputs The number next to each BNC reflects the actual input numbers The 2016 AVIM 2 as seen in Figure 17 has eight BNC connectors for the upper group of eight video inputs and one 34 pin connector The number next to the BNC reflects the actual input numbers T
69. 6660z2 3 300000000 0 266660666 E Ol Ol E 8 E Ol E 606066060606 Ze 160000000 160000000 2 8 23 300000000 56060000620 8 2660660666 EEUU TU UU UU 300000000 OUT OUT OUT OUT OUT OUT OUT OUT OUT OUT OUT OUT VIDEO INTERCONECT TO MONITOR CARDS VIDEO INTERCONECT TO MONITOR CARDS 2000000002 VIDEO INTERCONECT TO MONITOR CARDS VIDEO INTERCONECT TO MONITOR CARDS _ LINE TO BAYS SAV8 OL INI VILYA 16 WHO SZ lt ai ZH 09 05 OVA 00
70. 6666666666 20000000000000000 50006000000000000 00006000000000000 30000000000000000 0000000000000000 0006000000000000 0666666666666666 0666666666666666 10000000000000000 0666666666666666 9066 555 9 In 9995555 59 99999595 DATA LINE 5 A5 16 0000 960 INPUTS X 16 OUTPUTS Page 2 Level 1 4 Bays VIDEO INTERCONNECT TO MONITOR CARDS 16 241 LINE N 120 VAC 50 60 Hz C 5 66 99499669 r6000000000000000 6666666666666966 10000000000000000 20000000000000000 2 0000000000000000 5 000090000900090000 80000000000000000 200900009000000000 0000000000000000 0000000000000000 0666066666669606 00600000000000000 56000060000000000 800660000000000000 257 16 497 N 120 VAC 50 60 Hz SYNC at LINE 9999994904449960 H60060000000000060 5
71. Model AD1024 MegaPower II Matrix Switching Bays Installation and Operating Instructions This manual describes the installation and operating procedures for the American Dynamics model AD1024 Matrix Switching System Bays The AD1024 MegaPower II is designed as an integrated matrix switching and control system for CCTV surveillance systems having multiple cameras multiple monitors and multiple control stations The AD1024 Systems consist of a matrix switching bay its power supply module a data receiver buffer module the required video input modules VIM video output modules and appropriate rear panels This software firmware is confidential to and is copyrighted SENSORMATIC ELECTRONICS CORPORATION It is not to be copied or disclosed in any manner without the express written consent of SENSORMATIC The software is furnished to the purchaser under a license for use on a single system NOTE Information furnished by SENSORMATIC is believed to be accurate and reliable However no responsibility is assumed by SENSORMATIC for its use nor for any infringements of other rights of third parties which may result from its use No license is granted by implications or otherwise under any patent or patent rights of SENSORMATIC Copyright 1999 by SENSORMATIC rights reserved AMERICAN 05 The installation of this product should be made by gualified service personnel and should conform to all local codes
72. R 5 5008 amp 5 5 Es a S b 2442 220 Babe 0220 be 59 28 E i 66d 66do d ooo 66666666 8 2000009 e 60660666 6 2660060000 8 5 6760000000 266006000 8 2066060000 300000000 800600060 5 566000000 3 3 200000000 8 2666060000 s 06560600600 2666000606 5 500000006 266000000 s 500600006 Et666000060 Ss 260000006 566000000 8 3 Reooooooos s 266000606 23 560000000 8 360000000 200000000 5 TEE 420 52 Cho PHAR N 9090069096595050 Q 5660600000 8 66600000 8 B 5600006000 8 560000000 8 50 0 09 069999 1 5555 9 6666600000000 6660000000000 09 2900000008 2000000002 26060006008 766000006 4000400000000 0004000000 56000000000000 56000000009000 32 0000 31 0000 8 448 INPUTS X 32 OUTPUTS Level 2 4 Bays DATA LINE LAN 1 FROM CPU
73. System 43 SYSTEM CONFIGURATIONS SYSTEM CONFIGURATIONS LEVEL 3 960 A 48 Twelve Bay System The twelve bay Level 3 system allows a maximum of 960 video inputs switched to a maximum 48 video outputs Bays one two three five six seven nine ten and eleven consists of 256 video inputs each bay four consists of 192 video inputs with the first group 16 video outputs bay eight consists of 192 video inputs with the second group 16 video outputs bay twelve consists of 192 video inputs with the third group 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024VOM 1 modules in bay four followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 for connection to the 2024VOM 1 modules in bay four followed by sixteen 2016AVIM 2 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 31 with 16 for connection to the 2024VOM 1 modules in bay four followed by sixteen 2016AVIM 2 modules inputs 513 768 From the rear of bay four the modules are installed at the factory
74. VIM 2 is identified with the camera input icon 27 SYSTEM CONFIGURATIONS The starting camera number for the particular VIM is located at the top BNC Each 2016AVIM 2 includes eight BNCs for video input connections a coaxial ribbon connector labeled OUT for video interconnection and one 16 conductor coaxial video cable See Figure 17 Video Input Module page 8 The 2016AVIM 3 is identified with the camera input icon The starting camera number for the particular VIM is located at the top BNC Each 2016AVIM 3 includes eight BNCs for video input connections two coaxial ribbon connectors labeled IN and OUT and one 75 ohm terminator See Figure 18 Video Input Module page 8 Connect one end of the supplied coaxial ribbon cable to the coaxial ribbon connector labeled OUT of the 2016AVIM 2 NOTE Tighten the two connector screws alternately to keep the connectors aligned Tightening on one side only may damage the connector Alternate turns between each side Connect the other end of the coaxial ribbon cable to the coaxial ribbon connector labeled IN of the 2016AVIM 3 following the alternating turn method noted above Place a 75 ohm terminator P N 2016 TERM in the coaxial ribbon connector labeled OUT of the 2016AVIM 3 Continue in this manner for each 2016AVIM pair pair meaning the upper and lower halves of multiples of 16 for example 1 to 8 and 9 to 16 being a pair 17 to 24 and 25 to 32 being a pair In succession
75. VL module must be placed in the matrix switching bay that is connected to the highest numbered monitor output and this bay must contain Video Input Modules The 2010DBVL cannot be used in a switching bay that does not include Video Input Modules Front Panel The front panel of the 2010DBVL provides indicator LED s that illuminate if a video or sync loss is detected and indicate the SYNC and VIDEO content of the video input signal being monitored See Figure 9 for location of these LED s ALARM SYNC Ce lt lt indicates Sync present a indicates Video or Sync Loss VIDEO LEVEL Mce gt 4_ indicated Medium video content Loe a indicates High video content indicates Low video content Figure 9 2010DBVL Front Panel LED Indicators Rear Panels The 2010DBVL rear panel has 15 video output BNC s for connection to Video Output Modules and one 8 pin 45 RS 232 connector for Video Loss Detection data output and Alarm Contact output to an Alarm Interface Unit Figures 9 through 15 show the various types of rear panels of the Video Loss Detector Data Buffer module Icon Definition The gt icons on the rear panels are the video interconnect symbol for connecting switched video among the matrix switching bays lt gt Switched video inputs from cameras 1 to 256 ZEE Switched video inputs from cameras 257 to 512 Switched video inputs from cameras 513 to 768 Switche
76. VOM 1 modules outputs 33 48 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 3 192 X 48 Three Bay System and connect all bays in a similar manner 38 Video Interconnections The 16 video outputs from bay 1 bay 3 and bay 5 located on the rear panel of the 2010DB 11 12 and 13 respectively are grouped by fours and identified by the icon lt gt Each 2024 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four BNCs is used for video output connections The left most 2024VOM 1 module is assigned to outputs 1 4 the next for outputs 5 8 etc Using high grade RG 59U video cables connect the top most BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024 1 in bay 2 for output 1 matching icon to icon lt gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 1 Proceed to the next group of four BNCs on the 2010DB 11 of the first bay and connect these four to the second 2024VOM 1 in the second bay for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to 2024VOM 15 for outputs 1 16 Connect the top most BNC from bay 3 on the 2010DB 12 panel numbered 17 to the 2024VOM 1 in bay 4 for output 17
77. ar of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 3 modules for inputs 1 192 and four 2024VOM 1 modules for outputs 17 32 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect Connect a 75 ohm coaxial cable from the DATALINE 1 output on the AD1024 CPU to the DATA IN BNC of Bay 1 Connect a 75 ohm coaxial cable from the DATA OUT BNC of bay 1 to the DATA IN BNC 2010PS rear panel of Bay 2 Connect a 75 ohm BNC terminator supplied with the CPU to the DATA OUT BNC of Bay 2 Video Input Connections The 2016AVIM 2 is identified with the camera input icon The starting camera number for the particular VIM is located at the top Each 2016AVIM 2 includes eight BNCs for video input connections a coaxial ribbon connector labeled OUT for video interconnection and one 16 conductor coaxial ribbon cable See Figure 17 Video Input Module page 8 28 The 2016AVIM 3 is identified with the camera input icon The starting camera number for the particular VIM is located at the top BNC Each 2016AVIM 3 includes eight BNCs for video input connections two coaxial ribbon connectors labeled IN and OUT and one 75 ohm terminator See Figure 18 Video Input Module page 8 Connect one end o
78. ay System LEVEL 3 512 48 Seven Bay System seven bay Level 3 system allows a maximum of 512 video inputs switched to a maximum 48 video outputs Bays one through six consists of 256 video inputs and bay seven consists of 48 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024 1 modules in bay seven followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 for connection to the 2024 1 modules in bay seven followed by sixteen 2016AVIM 2 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024VOM 1 modules in bay seven followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 22 with 16 BNCs for connection to the 2024 1 modules in bay seven followed by sixteen 2016AVIM 3 modules inputs 257 512 From the rear of bay five the modules are installed at the
79. ble during the installation procedure It is much easier to remove a few temporary terminations or connections after a confirmation check than it is to disconnect and re wire a large number of permanent connections To facilitate maintenance and assist in service all connecting cables should be identified with source destination numbers 19 m 10 5 AD Y Figure 24 Bay Mounting Dimensions 5 SETUP Internal Jumper Switches Table 1 S2 and S3 switch settings 1 O Off X Don CAUTION Due to the presence of non insulated components with hazardous voltages the following internal adjustments should be performed by qualified service personnel only Filter 12345678 Pass all information S2 ON 10 Pass only specified information 52 OFF 00 Data Buffer Module Switches Note 52 must be set to pass all information ON in The 2010DB Data Buffer Module serves a dual purpose First bays which contain 2024VOM monitor modules it sends video to the monitors and second it filters incoming information from the high speed LAN line Switch S3 Filtering is accomplished with two 8 position DIP switches S2 Camera Monitor 12 456178 and S3 Switch position 1 of switch S2 turns the filter or 556 x x OFF If S2 is set to ON all information passes and S3 does
80. ccession connect the video inputs to each 2016AVIM 1 module top to bottom Each VIM will accept 16 video inputs Continue until all inputs are connected to the system Unused video inputs on the VIM do not require any external connection or termination and may be left open See Figure 16 Video Input Module page 8 Video Output Connections Each 2024 1 has a rear panel with 16 BNCs For single bay systems only the bottom four BNCs are used for video output connections The left most module is assigned to outputs 1 4 Moving left to right the next VOM module is assigned to outputs 5 8 etc The modules are numbered 4 5 8 etc Connect the video outputs to any device that accepts standard video such as monitors or video recorders See Figure 21 Video Output Module page 9 In the Appendix see Figure A2 192 X 16 One Bay System SYSTEM CONFIGURATIONS LEVEL 1 448 X 16 Two Bay System A two bay Level 1 system allows a maximum of 448 video inputs switched to a maximum 16 video outputs Bay one consists of the first 256 video inputs Bay two consists of the remaining 192 video inputs and four video output modules From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024 1 modules in bay two followed by sixteen 2016AVIM 1 modules for inputs 1 256 From the rea
81. cleaning interference and 2 This device and inspection For specific recommendations refer to the SAFEGUARDS sh k ith thi duct must accept any interference SAFEGU S sheet packaged with this produc received including interference INSTALLATION AND SERVICE that may cause undesired operation If you require information during installation of this product or if service seems necessary contact the Sensormatic Repair and Service Department at 800 442 2225 You must obtain a Return Authorization Number and shipping instructions before returning any product for service Do not attempt to service this product yourself Opening or removing covers may expose you to dangerous voltages or other hazards Refer all servicing to qualified personnel QA301D CONTENTS Page General 1 System Modules Description Power Supply Module 2010P rt ti ctt rte 2 Data Buffer Module 2010DB e ette Paci tne anane anana anane 4 Video Loss Detection Data Buffer 2010DB VL 6 Video Input Module 2016AV IM ore trie 8 Video Output Module 2024 VOM iecit 9 Master Date Time Module 2024MDT 10 Installation SOUC M a ga Kh 11 deem en 11 MT 11 Setup Data Butler Dan ng nd v 12 Video
82. connect the video inputs to the 2016AVIM 2 and 2016AVIM 3 module pairs Connect eight video inputs to 2016AVIM 2 and the next eight video inputs to 2016AVIM 3 Continue in this fashion until all video inputs are connected Unused video inputs do not require any external connection or termination and may be left open Video Output Connections Each 2024VOM 1 has a rear panel with 16 BNCs The left most module is assigned to outputs 1 4 Moving left to right the next module is for outputs 5 8 the next module is for outputs 9 12 the next for outputs 13 16 Continuing left the next four positions are for 2016AVIM modules The following four positions are for video outputs 17 32 Connect the video outputs to any device that accepts standard video such as monitors or video recorders In the Appendix see Figure A6 64 X 32 One Bay System SYSTEM CONFIGURATIONS LEVEL 2 192 X 32 Two Bay System A two bay Level 2 system allows a maximum of 192 video inputs switched to a maximum 32 video outputs Bay one consists of 192 video inputs with the first group of 16 video outputs Bay two consists of the same 192 video inputs with the second group of 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 2 modules for inputs 1 192 and four 2024VOM 1 modules for outputs 1 16 From the re
83. cted to the 2024VOM 2s for outputs 1 16 See Appendix Figure A18 Video Interconnections for illustration of these interconnections If there are less than four 2024 2 modules in the system the remaining BNCs on the 2010DB XX do not require any connection SYSTEM CONFIGURATIONS Video Input Connections See LEVEL 1 448 X 16 Two Bay System and connect in a similar manner Video Output Connections Each 2024 2 has a rear panel with 20 BNCs The right most module is assigned to outputs 1 4 The next module is for outputs 5 8 etc The modules are numbered 1 4 5 8 etc Connect video outputs to any device that accepts standard video such as monitors or video recorders 26 LEVEL 2 SYSTEMS Level 2 systems use up to nine matrix switching bays each with the 2010PS Power Supply Module and either the 2010DB or the 2010DBVL Data Buffer Module Depending on the configuration either 2010R Standard bays or 2020R Condensed bays are used in Level 2 systems Level 2 systems can consist of a maximum of 1024 video inputs as well as a maximum of 32 video outputs 31 outputs if the 2010DBVL module is used For a Level 2 system with Video Loss Detection capability the video output for monitor 32 is replaced by the Video Loss Detection function in the 2010DBVL Module Since each 2010DBVL can detect video losses for a maximum of 256 cameras an additional 2010DB VL Module is required for each block of 256 cameras The camera bays
84. ction to the 2024VOM 1 modules in bay three followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 for connection to the 2024VOM 1 modules in bay three followed by sixteen 2016AVIM 2 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010 5 the next module is the 2010DB 00 followed by twelve 2016AVIM 2 modules for inputs 513 704 and four 2024VOM 1 modules for outputs 1 16 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024VOM 1 modules in bay six followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 22 with 16 BNCs for connection to the 2024 1 modules in bay six followed by sixteen 2016AVIM 3 modules inputs 257 512 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010 5 the next module is the 2010DB 00 followed by twelve 2016AVIM 3 modules for inputs 513 704 and f
85. d video inputs from cameras 769 to 1024 lt gt lt See Appendix Figure 22 for illustration of interconnection from these modules to the Video Output Modules dco Figure 10 Figure 11 2010DBVL 00 2010DBVL 01 Rear Panel Rear Panel Camera Card Bay No Monitor Modules When video loss is detected a video loss message is transmitted from the 2010DBVL via the RJ45 connector RS 232 pins An alarm contact is also provided by pins 1 and 2 of this connector The connector pin definitions are as follows RJ45 Connector Pin Definitions Function RS 232 Code Alarm Contact Output Alarm Ground Receive Data RCD Transmit Data XMIT Ground GND 2 1 The 5 232 pins are connected to RS 232 port on AD1024 CPU which is set for VIDEO LOSS use The RS 232 port can be connected using the supplied modularcable if the distance between the 2010DBVL and the CPU is less than 7 feet If the distance exceeds 7 feet or if the Alarm Contact output is used an 8 pin Terminal Box is provided for connections The Terminal Box is connected to the 2010DBVL RS 232 port with the supplied modular cable The maximum cable length between an RS 232 device and the Terminal Box is 1000 feet using 18 AWG shielded computer grade cable p a
86. dule is similar to the 2010DB with the added capability of video loss detection for each camera of the bay A video loss detection message is transmitted via the RJ45 port on the 2010DBVL rear panel An Alarm Contact is also provided from this port see connector pinouts page 7 The 2010DBVL is configured with a 2 position slide switch S1 and three 8 position DIP switches S2 53 and 54 S1 is set for normal test mode as described for the 2010DB module DIP switch S2 sets the filtering mode as described for the 2010DB the Alarm Contact mode and the RJ45 port baud rate Switch position 2 of S2 must be set to ON for the module to function as a Video Loss Detection module The Alarm Contact modes are Alarm during Video or Sync Loss The Alarm Contact is closed and the ALARM LED on the 2010DBVL front panel is illuminated when a sync or video loss is first detected both remain on until the loss is cleared Alarm during loss plus 10 seconds The Alarm Contact is closed and the ALARM LED is illuminated as above but both remain on for 10 seconds after the loss is cleared Alarm at loss for 10 seconds The Alarm Contact is closed and the ALARM LED is illuminated as above but both remain on for only 10 seconds Alarm at loss for 20 seconds The Alarm Contact is closed and the ALARM LED is illuminated as above but both remain on for only 20 seconds The baud rate setting of DIP switch S2 configures the RJ45 port on the 201
87. er the far right module is the 2010PS the next module is the 2010DB 21 with 16 BNCs for connection to the 2024VOM 1 modules in bay three followed by sixteen 2016AVIM 2 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 2 modules inputs 513 704 and four 2024VOM 1 modules outputs 1 16 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024VOM 1 modules in bay six followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 22 with 16 for connection to the 2024VOM 1 modules in bay six followed by sixteen 2016AVIM 3 modules inputs 257 512 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010 5 the next module is the 2010DB 00 followed by twelve 2016AVIM 3 modules inputs 513 704 and four 2024 1 modules outputs 17 32 From the rear of bay seven the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 13 with 16
88. era number for the particular VIM is located at the top BNC Each 2016AVIM 1 includes 16 terminated BNCs for video input connections The first 2016AVIM 1 located immediately to the left of the 2010DB 01 is for video inputs 1 16 the second 2016AVIM 1 module is for inputs 17 32 etc In succession connect the video inputs to each 2016AVIM 1 module top to bottom Each VIM will accept 16 video inputs Continue until all inputs are connected to the system Unused video inputs on the VIM do not require any external connection or termination and may be left open See Figure 16 Video Input Module page 8 Video Output Connections with No Titles Each 2010DB 01 in the system has 16 BNCs The top most BNC corresponds to video output 1 and the bottom video output corresponds to number 16 Connect the video outputs to any device that accepts standard video such as monitors or video recorders See Figure 4 2010DB 01 Rear Panel with 16 BNCs page 4 In the Appendix see Figure A1 256 X 16 One Bay System with No Titles LEVEL 1 256 X 15 Bay System with Video Loss Detection A one bay Level 1 system with video loss detection and without video titles allows a maximum of 256 video inputs switched to a maximum of 15 video outputs This system is the same configuration of modules as the LEVEL 1 256 X 16 system except that the 2010DBVL 01 Video Loss Detection Data Buffer module is installed in place of the 2010DB 01 module
89. erconnections for illustration of these connections If there are less than twelve 2024 28 in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 3 256 X 48 three bay system and connect in a similar manner Video Output Connections Each 2024VOM 2 has a rear panel with 20 BNCs The right most module is assigned to outputs 1 4 The next module is for outputs 5 8 etc The modules are numbered 1 4 5 8 etc Connect video outputs to any device that accepts standard video such as monitors or video recorders ADULP LOOPING PANEL ADULP Loop Panel used with AD1024 Systems For information on the use of the AD Universal Loop Panel ADULP with AD1024 or AD2050 switching systems see AD Universal Loop Panel Installation Instructions Part Number 8000 0900 01 48 Appendix 256 INPUTS X 16 OUTPUTS With No TITLES Level 1 1 Bay 120V 60Hz PROG MON PORTS 7 DATA AD1024 CPU rj E3 E3 E3 ooo oo 2 1 DATA LINE LAN 241 2 e OUT 120 VAC 50 60 Hz ATA LINE a 66090000 00000006 9 999 OOOO OOOOOOOO 0900000 766000600000000000 600006060000000000 66000060000000000 50600000000000000
90. f bay two the modules are installed at the factory in the following manner the far right module is the 2010 5 the next module is the 2010DB 00 followed by twelve 2016AVIM 3 modules and four 2024 1 modules inputs 1 192 outputs 17 32 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 4 modules and four 2024 1 modules inputs 1 192 outputs 33 48 IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect Connect a 75 ohm coaxial cable from the DATALINE 1 output on the AD1024 CPU to the DATA IN BNC of bay 1 Connect a 75 ohm coaxial cable from the DATA OUT BNC of bay 1 to the DATA IN BNC on the 36 2010PS rear panel in bay 2 Connect a 75 ohm coaxial cable from the DATA OUT BNC of bay 2 to the DATA IN BNC 2010PS rear panel in bay 3 Connect a 75 ohm BNC terminator supplied with the CPU to the Data OUT BNC of bay 3 Video Input Connections The 2016AVIM 2 is identified with the camera input icon The starting camera number for the particular VIM is located at the top BNC Each 2016AVIM 2 includes 8 for video input connections a coaxial ribbon connector labeled OUT for video interconnection and one 16 conductor coaxial ribbon cable See Figure 17 Video Input Module page 8 The 2016AVIM 3 is identified with the camera input icon The starting camera
91. f the supplied coaxial ribbon cable to the coaxial ribbon connector labeled OUT of the 2016AVIM 2 NOTE Tighten the two connector screws alternately to keep the connectors aligned Tightening on one side only may damage the connector Alternate turns between each side Connect the other end of the coaxial ribbon cable to the coaxial ribbon connector labeled IN of the 2016AVIM 3 following the alternating turn method noted above Place a 75 ohm terminator P N 2016 TERM in the coaxial ribbon connector labeled OUT of the 2016AVIM 3 Continue in this manner for each 2016AVIM pair A pair meaning the upper and lower halves of multiples of 16 for example 1 to 8 and 9 to 16 being a pair 17 to 24 and 25 to 32 also being a pair In succession connect the video inputs to the 2016AVIM 2 and 2016AVIM 3 module pairs Connect eight video inputs to 2016AVIM 2 and the next eight video inputs to 2016AVIM 3 Continue in this fashion until all video inputs are connected Unused video inputs do not require any external connection or termination and may be left open Video Output Connections Each 2024VOM 1 has a rear panel with 16 BNCs The bottom four BNCs are used for video output connections The right most module is assigned to outputs 1 4 the next for outputs 5 8 etc The modules are numbered 1 4 5 8 etc Connect the video outputs to any device that accepts standard video such as monitors or video recorders Bay one contains the 2
92. for example 1 to 8 and 9 to 16 being a pair 17 to 24 and 25 to 32 also being a pair In succession connect the video inputs to the 2016AVIM 2 and 2016AVIM 3 module pairs Connect eight video inputs to 2016AVIM 2 and the next eight video inputs to 2016AVIM 3 Continue in this fashion until all video inputs are connected Unused video inputs do not require any external connection or termination and may be left open Video Output Connections Each 2024 1 has a rear panel with 16 BNCs The bottom four are used for video output connections The left most module is assigned to outputs 1 4 the next for outputs 5 7 etc Connect the video outputs to any device that accepts standard video such as monitors or video recorders Bay one contains the 2024VOMs for outputs 1 16 bay two for outputs 17 32 and bay three for outputs 33 48 In the Appendix see Figure 12 192 X48 Three Bay System LEVEL 3 256 X 48 Four Bay System A four bay Level 3 system allows a maximum of 256 video inputs switched to a maximum 48 video outputs Bays one through three consists of 256 video inputs and bay four consists of 48 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024 1 modules in bay four followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two
93. four BNCs on the 2010DB 11 panel Connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to all of the 2024 1 modules If there are less than four 2024 modules in the system leave the remaining BNCs on 2010DB 11 of bay 1 open 22 Video Input Connections The 2016AVIM is identified with the camera input icon The starting camera number for the particular VIM is located at the top BNC Each 2016AVIM 1 includes 16 terminated for video input connections The first 2016AVIM module is for video inputs 1 16 the second VIM module is for inputs 17 32 etc In succession connect the video inputs to each 2016AVIM 1 module top to bottom Each VIM will accept 16 video inputs Continue until all inputs are connected to the system Unused video inputs on the VIM do not require any external connection or termination and may be left open See Figure 16 Video Input Modules page 8 Video Output Connections Each 2024VOM 1 has a rear panel with 16 BNCs only the bottom four BNCs are used for video output connections The left most module is assigned to outputs 1 4 Moving left to right the next VOM module is assigned to outputs 5 8 etc The modules are numbered 1 4 5 8 etc Connect the video outputs to any device that accepts standard video such as monitors or video recorders See Figure 21 Video Output Module page 9
94. from these outputs contain no character information only standard video The second purpose of the Data Buffer is to filter incoming system information from the DATA LINE Filtering is performed to allow for the passage of localized information The 2010DB rear panel has 16 video output BNC s for connection to Video Output Modules in other switching bays The illustrations in Figures 3 through 8 show the various types of rear panels of the Data Buffer module See Appendix Figure A22 for illustration of interconnection from these modules to the Video Output Modules Icon Definition The gt 15 the video interconnect symbol for connecting switched video among the matrix switching bays gt Switched video inputs from cameras 1 to 256 ZEE Switched video inputs from cameras 257 to 512 E Switched video inputs from cameras 513 to 768 Switched video inputs from cameras 769 to 1024 l Output 1 O Output 1 02 Q on 8 Output 8 O 8 Output 8 9 on on o On gt or on O16 Output 16 6 Output 16 Figure 3 Figure 4 Figure 5 2010DB 00 2010DB 01 2010DB 11 to 2010DB 18 Rear Panel Rear Panel w 16 BNCs Rear Panel w 16 BNCs Camera Card Bay Multiple Bay System No Monitor Modules for cameras 1 256 Data Buffer Module 201
95. he 2024VOM 2 in bay 13 for output 1 matching icon to icon 47 SYSTEM CONFIGURATIONS Continue in this manner until connections 1 4 of the 2010DB 41 panel are connected to inputs 1 4 of the 2024VOM 2 Proceed to the next group of four on the 2010DB 41 and connect these to the second 2024VOM 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 41 panel are connected to the 2024VOM 2s for outputs 1 16 Connect bay 8 in a similar manner to the 2024VOM 2s in bay 13 for video outputs 17 32 matching icon to icon Connect the topmost BNC from bay 9 on the 2010DB 13 panel numbered 33 to the 2024VOM 2 in bay 14 for output 33 matching icon to icon lt gt Continue in this manner until connections 33 36 of the 2010DB 13 panel are connected to inputs 33 36 of the 2024VOM 2 of bay 14 Proceed to the next group of four on the 2010DB 13 and connect these four to the second 2024 2 for outputs 37 40 Continue in this manner until all 16 connections of the 2010DB 13 panel are connected to the 2024VOM 25s for outputs 33 48 Connect bay 10 in a similar manner to the 2024VOM 2s of bay 14 for video outputs 17 32 matching icon to icon Connect bay 11 in a similar manner to the 2024VOM 2s of bay 14 for video outputs 33 48 matching icon to icon Connect bay 12 in a similar manner to the 2024VOM 2s for video outputs 33 48 matching icon to icon See Appendix Figure A18 Video Int
96. he third rear panel 2016AVIM 3 as seen in Figure 18 has eight BNC connectors for the lower group of eight cameras to complete the larger group of 16 video inputs and two 34 pin connectors The number next to the BNC reflect the actual input numbers The fourth type of rear panel 2016AVIM 4 as seen in Figure 19 has only two 34 pin connectors They are used for expansion in multiple switching bay configurations EN EN _ 16 000000000 NGO 0 2 2 Figure 18 2016AVIM 3 Figure 19 2016AVIM 4 Video Output Module 2024 The 2024VOM Video Output Module creates the titles that are added to the video output Each module has four video outputs on its rear panel Front Panel Front panel controls on the Video Output Module adjust the brightness vertical and horizontal position for each title displayed on each of the four video outputs The 4 position rotary switch on the front panel governs which output you control The front panel LED blinks to verify proper operation of the 2024VOM See Figure 20 below Further details on operation of these controls is provided in the Video Output Module SETUP description page 17 a Blinking LED for proper operation D 4 4 position rotary switch A Horizontal control push button 4 4 Vertical control
97. ideo outputs 1 16 matching icon to icon Connect bay 4 in a similar manner to the 2024VOM 1 modules of bay for video outputs 17 32 matching icon to icon lt gt Connect bay 5 in a similar manner to the 2024VOM 1 modules of bay 6 for video outputs 17 32 matching icon to icon See Appendix Figure A18 Video Interconnections for illustration of these connections If there are less than eight 2024VOMs in the system the remaining BNCs on the 2010DR XX do not require any connection Video Input Connections See LEVEL 2 192 X 32 Two Bay System and connect in a similar manner Video Output Connections See LEVEL 2 192 X 32 Two Bay System and connect in a similar manner In the Appendix see Figure A10 LEVEL 2 704 X 32 Six Bay System SYSTEM CONFIGURATIONS LEVEL 2 960 X 32 Eight Bay System An eight bay Level 2 system allows a maximum of 960 video inputs switched to a maximum 32 video outputs Bays one two and three each consist of 256 video inputs Bay four consists of 192 video inputs with the first group 16 video outputs Bays five six and seven also each consist of 256 video inputs Bay eight consists of 192 video inputs with the second group 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024VOM 1 modules in bay four followed by
98. ilar manner to the 2024VOM 1s of bay 9 for video outputs 33 48 matching icon to icon gt See Appendix Figure A18 Video Interconnections for illustration of these connections If there are less than twelve 2024VOM 1s in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner Video Output Connections See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner In the Appendix see Figure A15 704 X 48 Nine Bay System 41 SYSTEM CONFIGURATIONS SYSTEM CONFIGURATIONS LEVEL 3 768 X 48 Ten Bay System A seven bay Level 3 system allows a maximum of 768 video inputs switched to a maximum 48 video outputs Bays one through nine consists of 256 video inputs and bay ten consists of 48 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024 1 modules in bay ten followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 BNCS for connection to the 2024 1 modules in bay ten followed by sixteen 2016AVIM 2 modules inputs 257 512 From the rear of bay three the
99. illustration of these connections If there are less than eight 2024VOM 1 modules in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 2 192 X 32 Two Bay System and connect in a similar manner Video Output Connections See LEVEL 2 192 X 32 Two Bay System and connect in a similar manner In the Appendix see Figure A8 448 X 32 Four Bay System SYSTEM CONFIGURATIONS LEVEL 2 448 X 32 Four Bay System A four bay Level 2 system allows a maximum of 448 video inputs switched to a maximum 32 video outputs Bay one consists of 256 video inputs bay two consists of 192 video inputs with the first group of 16 video outputs Bay three consists of 256 video inputs bay four consists of 192 video inputs with the second group of 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024 1 modules in bay two followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 2 modules for inputs 257 448 and four 2024VOM 1 modules for outputs 1 16 From the rear of bay three the modules are installed at the factory in the follo
100. in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 2 modules and four 2024VOM 1 modules inputs 769 960 and outputs 1 16 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024VOM 1 modules in bay eight followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 22 with 16 BNCs for connection to the 2024VOM 1 modules in bay eight followed by sixteen 2016AVIM 3 modules inputs 257 512 From the rear of bay seven the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 32 with 16 for connection to the 2024VOM 1 modules in bay eight followed by sixteen 2016AVIM 3 modules inputs 513 768 From the rear of bay eight the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by 44 twelve 2016AVIM 3 modules and four 2024VOM 1 modules inputs 769 960 and outputs 17 32 From the rear of bay nine the modules are installed at the factory in the following manner the far right module is the 2010PS the next m
101. in the following manner the far right module is the 2010PS the next module is the 2010DB 41 with 16 for connection to the 2024VOM 2 modules in bay thirteen followed by sixteen 2016AVIM 2 modules inputs 769 1024 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024VOM 2 modules in bay thirteen followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 22 with 16 for connection to the 2024VOM 2 modules in bay thirteen followed by sixteen 2016AVIM 3 modules inputs 257 512 From the rear of bay seven the modules are installed at the factory in the following manner the far right module is the 2010PS next module is the 2010DB 32 with 16 BNCs for connection to the 2024VOM 2 modules in bay thirteen followed by sixteen 2016AVIM 3 modules inputs 513 768 From the rear of bay eight the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 42 with 16 for connection to the 2024VOM 2 modules in bay thirteen followed by sixteen 2016AVIM 3 modules inputs 769 1024 46 From the rear of bay nine the modules are installed at the factory in
102. ing high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024 1 in bay 3 for output 1 matching icon to icon gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024VOM 1 Proceed to the next group of four BNCs on the 2010DB 11 of the first bay and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to the 2024 1 for outputs 1 16 Connect bay 4 in a similar manner to the 2024VOM 1s of bay for video outputs 17 32 matching icon to icon lt gt Connect bay 7 in a similar manner to the 2024VOM 1s of bay 9 for video outputs 33 48 matching icon to icon gt Connect the topmost BNC from bay 2 on the 2010DB 21 panel numbered 1 to 2024VOM 1 in bay 3 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 12 panel are connected to inputs 1 4 of the 2024VOM 1 of bay 3 Proceed to the next group of four on the 2010DB 12 and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 21 panel are connected to 2024 1 5 for outputs 1 16 Connect bay 5 in a similar manner to 2024VOM 1 of bay 6 for video outputs 17 32 matching icon to icon gt Connect bay 8 in a sim
103. installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 for connection to the 2024VOM 1 modules in bay three followed by sixteen 2016AVIM 1 modules for inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010 5 the next module is the 2010DB 00 followed by twelve 2016AVIM 1 modules for inputs 513 704 and four 2024VOM 1 modules for outputs 1 16 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See Level 1 448 16 Two Bay System and connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 and bay 2 located on the rear panel of the 2010DB 11 and 2010DB 21 are grouped by fours Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four BNCs is used for video output connections See Figure 21 Video Output Module page 9 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the top most input BNC labeled 1 on the 2024VOM 1 in bay 3 for output 1 matching icon to icon Continue in this manner until BNCs 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024VOM 1
104. ion are set at the back of the card end with gold plated connections Each card can be set for monitors one two three and four or five six seven and eight or nine ten eleven and twelve or thirteen fourteen fifteen and sixteen There is no other variations only the four types described above Note The silkscreen labeling on the VOM board shows which jumper is for which monitor these are labeled M1 through M16 When setting monitors over sixteen subtract multiples of sixteen from the monitor number you want to set For example to set monitors 33 36 subtract 32 to obtain monitors one through four 33 32 1 35 3223 etc For selection of video type Phase Adjusted Line PAL or National Television Systems Committee NTSC locate the 2 position jumper terminal near the center edge of the card Position the plastic 2 pin jumper to the appropriate location For selection of bay configuration Standard or Condensed locate the 2 position jumper terminal near the center of the two gold connectors bays are configured with the jumper position set to standard bay In Condensed Bays the jumper 18 set to standard bay for cards corresponding to monitors 17 to 32 while the jumper is set to condensed or split bay for cards corresponding to monitors 1 to 16 NTSC PAL jumper Condensed or Standard Monitors S2 1
105. ional and local use code requirements DO NOT PHYSICALLY CONNECT EQUIPMENT TO THE POWER SOURCE UNTIL POWER UP PROCEDURES HAVE BEEN COMPLETED Read the section on POWERING UP page 19 before connecting the system to the power source and check the various System Configurations shown in the Appendix INSTALLATION Connections system connections are made on the rear panels of the system bays Connections for several typical System Configurations are described in pages 20 through 47 See the Appendix for illustrations of various system connections Note Make all internal jumper switch settings on the modules before system connections are started see SETUP pages 12 18 Be certain that all connections are properly completed before applying power video connections should be made using a good grade 75 ohm RG 59U video cable i e Belden 8241 or equivalent with BNC connectors video outputs must be terminated in 75 ohms at the last unit in the run Set the intermediate units to HiZ If the video run is not terminated or if it is double terminated the resulting picture will be of poor quality If the run is not terminated a brighter picture than desired will be displayed Conversely if the run is double terminated a darker picture than desired will be displayed Each installation should be made in a planned and orderly manner The operation of each piece of equipment should be confirmed as early as possi
106. lects one of three video sync references EXT V DRIVE Up position Selects the external vertical drive pulse input on the rear panel EXT SYNC IN EXT CAM Center position Selects composite video AC LINE Down position Selects the AC line as supplied 5 SYNC PHASE ADJUSTMENT This potentiometer accessed thru the hole in the front panel of the Power Supply adjusts the phase of the sync pulse with respect to the selected reference When the sync test switch is set to SET UP a horizontal trace line is displayed on Monitor 1 showing the location of the sync pulse with respect to the picture See Power Supply Setup page 18 6 9 VDC AND 9 VDC LED s These green LED s when illuminated indicate the presence of DC voltages Note For the 230 VAC systems the output voltages are 8 VDC 7 POWER ON OFF SWITCH This switch is used to apply power to the bay When the switch is in the ON position a green light is illuminated behind the Power On Off Switch O 1 SET UP NORMAL 5 SYNC toss O 3 EXT V DRIVE EXT CAM AC LINE z 4 PHASE 5 49VDC 9VDC 6 7 Figure 1 Front Panel of Power Supply Module Fusing Four replaceable fuses are located on the power supply circuit board Replacement fuses must meet national and local use code requirements Fuse Ratings For 120VAC Systems F1 125V 5 AMP 5 x 20
107. les in bay nine followed by sixteen 2016AVIM 2 modules inputs 769 1024 From the rear of bay five the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay six the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 22 with 16 for connection to the 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 3 modules inputs 257 512 From the rear of bay seven the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 32 with 16 BNCs for connection to the 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 3 modules inputs 513 768 From the rear of bay eight the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 42 with 16 BNCs for connection to the 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 3 modules inputs 769 1024 34 From the rear of bay nine the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by eight 2024VOM 2 modules installed left to right for output
108. manner to the 2024VOM 1s of bay 10 for video outputs 17 32 matching icon to icon Connect bay 8 in a similar manner to the 2024VOM 1s of bay 10 for video outputs 33 48 matching icon to icon Connect the topmost BNC from bay 3 on the 2010DB 31 panel numbered 1 to the 2024VOM 1 in bay 10 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 31 panel are connected to inputs 1 4 of the 2024VOM 1 Proceed to the next group of four on the 2010DB 12 and connect these four to the second 2024VOM 1 of bay 10 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 31 panel are connected to the 2024 18 for outputs 1 16 Connect bay 6 in a similar manner to the 2024VOM 1s of bay 10 for video outputs 17 32 matching icon to icon Connect bay 9 in a similar manner to the 2024VOM 1s of bay 10 for video outputs 33 48 matching icon to icon See Appendik Figure 18 Video Interconnections for illustration of these connections If there are less than twelve 2024VOM 1s in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner Video Output Connections video outputs are located in bay 4 See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner In the Appendix see Figure A16 768 X 48 Ten Bay
109. matching icon to icon lt gt Continue in this manner until connections 17 20 of the 2010DB 12 panel are connected to inputs 17 20 of the first 2024VOM 1 of the fourth bay Proceed to the next group of four BNCs on the 2010DB 12 panel of the third bay and connect these four to the second 2024 1 of the fourth bay for outputs 21 24 Continue in this manner until all 16 connections of the 2010DB 12 panel are connected to 2024 18 in the fourth bay for outputs 17 32 Connect the top most BNC from bay 5 on the 2010DB 13 panel numbered 33 to the 2024VOM 1 in bay 6 for output 33 matching icon to icon gt Continue in this manner until connections 33 36 of the 2010DB 13 panel are connected to inputs 33 36 of the first 2024VOM 1 of the sixth bay Proceed to the next group of four on the 2010DB 13 of the fifth bay and connect these four to the second 2024VOM 1 of the sixth bay for outputs 37 40 Continue in this manner until all 16 connections of the 2010DB 13 panel are connected to the 2024VOM 1s in the sixth bay for outputs 33 48 See Appendix Figure A18 Video Interconnections If there are less than twelve 2024VOM 1s in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner Video Output Connections See LEVEL 3 192 X 48 Three Bay System In the Appendix see Figure A14 448 X 48 Six B
110. ner In the Appendix see Figure All Level 2 960 X 32 Eight Bay System 33 SYSTEM CONFIGURATIONS SYSTEM CONFIGURATIONS LEVEL 2 1024 X 32 Nine Bay System A nine bay Level 2 system allows a maximum of 1024 video inputs switched to a maximum 32 video outputs Bays one through eight each consists of 256 video inputs and bay nine consists of the first 32 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 for connection to the 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 2 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 31 with 16 for connection to the 2024VOM 1 modules in bay nine followed by sixteen 2016AVIM 2 modules inputs 513 768 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 41 with 16 for connection to the 2024VOM 1 modu
111. ng up instructions Power Supply Module and Video Output Module prior pages 6 To replace the front panel slip the bottom of the panel into the slot at the bottom of the bay Push the top of the panel towards the bay and tighten the two corner thumb screws POWER UP SYSTEM CONFIGURATIONS SYSTEM CONFIGURATIONS The following sections of this manual are organized specific to the system level to be installed A level is defined as 16 video outputs and may consist of one to several bays Level 1 is for a maximum of 16 outputs Level 2 is for 32 outputs and so on up to Level 8 which is for a maximum of 128 outputs System bays are supplied in the following two configurations Standard Model 2010R and Condensed Model 2020R References to Right or Left in the following instructions apply to the Bays as viewed from the REAR LEVEL 1 SYSTEMS Level 1 systems can have a maximum of five 2010R Standard matrix switching bays that each contain the 2010PS Power Supply Module and a 2010DB or 2010DBVL Data Buffer Module Level 1 Systems can consist of a maximum of AD1024 video inputs and a maximum of 16 video outputs 15 outputs if the 2010DBVL module is used For a Level 1 system with Video Loss Detection capability the video output for monitor 16 is replaced by the Video Loss Detection function in the 2010DBVL Module Since each 2010DBVL can detect video losses for a maximum of 256 cameras an additional 2010DB VL Module is requi
112. number for the particular VIM is located at the top Each 2016AVIM 3 includes 8 for video input connections two coaxial ribbon connectors labeled IN and OUT and one 75 ohm terminator See Figure 18 page 9 The 2016AVIM 4 is identified with the camera input icon The starting camera number for the particular VIM is located at the top of rear panel Each 2016AVIM 4 includes two coaxial ribbon connectors labeled IN and OUT for video interconnection and one 16 conductor coaxial ribbon cable Connect one end of the supplied coaxial ribbon cable to the coaxial ribbon connector labeled OUT of the 2016AVIM 2 NOTE Tighten the two connector screws alternately to keep the connectors aligned Tightening on one side only may damage the connector Alternate between each side Connect the other end of the coaxial ribbon cable to the coaxial ribbon connector labeled IN of the 2016AVIM 3 following the alternating turn method noted above Connect one end of the second coaxial ribbon cable supplied with the 2016AVIM 4 to the coaxial ribbon connector labeled OUT of the 2016AVIM 3 Connect the other end of the ribbon cable to the coaxial ribbon connector labeled IN of the 2016AVIM 4 following the alternating turn method above Place a 75 ohm terminator P N2016 TERM in the coaxial ribbon connector labeled OUT of the 2016AVIM 4 Continue in this manner for each 2016AVIM pair A pair meaning the upper and lower halves of multiples of 16
113. o 88 9990009009006900 0 134448 44978444 5604 00000000 8 boooooo o 00000000 San mam 2606000000 San 0000000 8 z 5 00000000 500000000 6 8 1 z 500000000 8 66666006208 5 5 6 3 R 190000000 a 8 1 100000000 z 6 200000000 2 66666662 8 2606000000 ze T 100000000 2 6666000620 Fooo00000 8 8ee0000oox 5 300000000 5000000092 5 34 06000000 200000000 5 500000 oo em o 5 5 52 40 5 44484441 66d 394904998994 599 400600000 8 25600006 Oz pees z 500000000 S 3 B60060606002 8 z 2566600060 8 500000000 so 26000000028 100000066 8 8 100000000 26000000028 206060000 8 866600000 ligeeeeeeees BR 200666006 8 300000000 8 5 30000000 8 zi 100000000 8 5 6600066002 8 3 zo 100000000 B 166000660602 8 m m lt 3666000
114. o the system Note Before adjusting all of the video inputs quickly scan all inputs to see if only a few are out of phase and adjust accordingly input one may be the only oddball Once all cameras have been synchronized place the SET UP NORMAL switch to the NORMAL position If multiple matrix switching bays are used repeat steps A H for each bay The sync test output for these bays is the top most output BNC located on each 2010DB XX rear panel at the first monitor of the bay i e monitor 17 32 etc 2 EXT V DRIVE If an external generator is used to control the vertical switching point switch the Sync Reference Selection switch to EXT V DRIVE external vertical drive For proper operation the output voltage of the generator should not exceed 5V peak to peak p p Connect the drive output from the generator to the EXT SYNC IN BNC located on the 2010PS rear panel Connect a 75 ohm terminator to the EXT SYNC OUT BNC If other bays are used loop the EXT SYNC from input to output for all bays and terminate the last bay EXT SYNC OUT BNC in 75 ohms 3 EXT CAM If composite video is used to control the vertical switching point switch the Sync Reference Selection switch to EXT CAM external camera For proper operation the composite sync signal is specified at 1 1V p p Connect the composite sync to the EXT SYNC IN BNC located on the 2010PS rear panel Connect a 75 ohm terminator to the EXT SYNC OUT BNC If other bays are used
115. odule is the 2010DB 13 with 16 BNCs for connection to 2024VOM 1 modules bay twelve followed by sixteen 2016AVIM 4 modules inputs 1 256 From the rear of bay ten the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 23 with 16 BNCs for connection to 2024VOM 1 modules bay twelve followed by sixteen 2016AVIM 4 modules inputs 257 512 From the rear of bay eleven the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 33 with 16 BNCs for connection to 2024VOM 1 modules in bay twelve followed by sixteen 2016AVIM 4 modules inputs 513 768 From the rear of bay twelve the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 4 modules and four 2024VOM 1 modules inputs 769 960 and outputs 33 48 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 3 192 X 48 three bay system and connect all bays in a similar manner Video Interconnections The 16 video outputs from bays 1 2 3 5 6 7 9 10 and 11 located on the rear panel of the 2010DB 11 12 13 2010DB 21 22 23 gt and 2010DB 31 32 33 respectivel
116. ons See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner Video Output Connections See LEVEL 3 192 X 48 Three Bay System and connect in a similar manner SYSTEM CONFIGURATIONS LEVEL 3 1024 X 48 Fourteen Bay System A fourteen bay Level 3 System allows a maximum of 1024 video inputs switched to a maximum 48 video outputs Bays one through twelve consists of 256 video inputs and bay thirteen consists of the first 32 video outputs and bay 14 consists of the second group of 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for connection to the 2024VOM 2 modules in bay thirteen followed by sixteen 2016AVIM 2 modules inputs 1 256 From the rear of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 21 with 16 for connection to the 2024VOM 2 modules in bay thirteen followed by sixteen 2016AVIM 2 modules inputs 257 512 From the rear of bay three the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 31 with 16 for connection to the 2024VOM 2 modules in bay thirteen followed by sixteen 2016AVIM 2 modules inputs 513 768 From the rear of bay four the modules are installed at the factory
117. or output 1 matching icon to icon it Continue in this manner until connections 1 4 of the 2010DB 41 panel are connected to inputs 1 4 of the 2024 2 Proceed to the next group of four on the 2010DB 41 and connect these to the second 2024 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 41 panel are connected to the 2024 2 modules for outputs 1 16 Connect bay 8 in a similar manner to the 2024 2 modules of bay 9 for video outputs 17 32 matching icon to icon it See Appendix Figure A18 Video Interconnections for illustration of these connections If there are less than eight 2024 2 modules in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 2 192 X 32 Four Bay System and connect all bays in a similar manner Video Output Connections Each 2024VOM 2 has a rear panel with 20 BNCs The right most module is assigned to outputs 1 4 The next module is for outputs 5 8 etc The modules are numbered 1 4 5 8 etc Connect video outputs to any device that accepts standard video such as monitors or video recorders 35 SYSTEM CONFIGURATIONS SYSTEM CONFIGURATIONS LEVEL 3 SYSTEMS Level 3 systems use up to fourteen 2010 matrix switching bays each with the 2010PS Power Supply Module and 2010DB XX Data Buffer module Level 3 systems can consist of up to 192 448 704 768 960 or 1024 video in
118. ost BNC from bay 2 on the 2010DB 21 panel numbered 1 to the 2024VOM 2 in bay 5 for output 1 matching icon to icon gt Continue in this manner until connections 1 4 of the2010DB 2 panel are connected to inputs 1 4 of the 2024 2 Proceed to the next group of four on the 2010DB 21 and connect these to the second 2024 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 21 panel are connected to the 2024VOM 2s for outputs 1 16 Connect the top most BNC from bay 3 on the 2010DB 31 panel numbered 1 to the 2024VOM 2 in bay 5 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 3 panel are connected to inputs 1 4 of the 2024 2 Proceed to the next group of four on the 2010DB 31 and connect these to the second 2024 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 31 panel are connected to the 2024VOM 2s for outputs 1 16 Connect the top most BNC from bay 4 on the 2010DB 41 panel numbered 1 to the 2024VOM 2 in bay 5 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the2010DB 41 panel are connected to inputs 1 4 of the 2024 2 Proceed to the next group of four on the 2010DB 41 and connect these to the second 2024 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 41 panel are conne
119. our 2024VOM 1 modules for outputs 17 32 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING 31 SYSTEM CONFIGURATIONS Data Interconnect See LEVEL 2 192 X 32 two bay system and connect all the bays in a similar manner Video Interconnections The 16 video outputs from bay 1 bay 2 bay 4 and bay 5 located on the rear panel of the 2010DB 11 2010DB 12 gt 2010DB 21 and 2010DB 22 ZR grouped by fours and identified by their icons Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four is used for video output connections See Figure 21 Video Output Module page 9 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the topmost input BNC labeled 1 for the 2024VOM 1 in bay 3 for output 1 matching icon to icon lt gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 1 Proceed to the next group of four BNCs on the 2010DB 11 of the first bay and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to all of the 2024VOM 1 modules lt gt Connect bay 2 in a similar manner to the 2024VOM 1 modules of bay 3 for v
120. output module monitor 1 If not use the Data Buffer output 1 From an external keyboard call input 1 to output 1 C Place the SET UP NORMAL switch to the SET UP position This implements the phase adjustment procedure Note The Sync Test On Off LED will be blinking when the sync test switch is in the SETUP position Notice that the alignment bar displayed on output 1 shows the location of the vertical switch with respect to the picture D The phase adjustment potentiometer accessed thru the hole in the front panel of the Power Supply adjusts the phase of the vertical interval synchronization pulse for the switcher with respect to the selected reference Adjust the position of the bar with a TV alignment tool or equivalent by turning the phase potentiometer until the line is located as seen in Figure 30 The line should be visible on the screen Once the alignment bar is set no further adjustment to the potentiometer is necessary Select the second video input in the system If the horizontal bar is not in the same location as seen in Figure 30 adjust the sync location on the video device i e video camera until the horizontal bar is located towards the bottom of the screen If this is not possible and the alignment bar is located in a different position than it was 18 in the previous camera you will experience camera roll during switching operations to that camera Repeat this for all video inputs t
121. push button Brightness control push button Figure 20 Video Output Module Front Panel Indicators and Controls SYSTEM MODULES DESCRIPTION Rear Panels The 2024VOM 1 rear panel as seen in Figure 21 has 16 BNC connectors The bottom four BNCs are video outputs while the remaining upper three groups each containing four are for video inputs from other matrix switching bays in the system The 2024 2 rear panel as seen in Figure 22 has four sections of four BNCs for video inputs from other matrix switching bays A fifth section of four BNCs in the lower left corner is used for video outputs B gt OOQO O OO C 4 Q 4 17 U e T 4 04 0 4 Figure 21 Figure 22 Video Output Module Video Output Module 2024 1 2024VOM 2 Rear Panel Rear Panel SYSTEM MODULES DESCRIPTION Master Date Time Module 2024MDT The 2024MDT Master Date Time Module provides looping connection of the video input signals and insertion of system time and date information on the video output connections These modules are used with dedicated inputs for dedicated outputs and do not perform any inter bay switching The 2024MDT has four looping video inputs and four separate video outputs with system time and date information Front Panel
122. puts and up to 48 video outputs arranged as 2 3 4 6 7 9 10 12 and 14 bay systems For a Level 3 system with Video Loss Detection capability the video output for monitor 48 is replaced by the Video Loss Detection function in the 2010DBVL Module Since each 2010DBVL can detect video losses for a maximum of 256 cameras an additional 2010DBVL Module is required for each block of 256 cameras The camera bays that contain video outputs for monitors 32 through 47 would use a 2010DB VL 13 a 2010DBVL 23 a 2010DBVL 33 and a 2010DBVL 43 for each respective group of 256 cameras In a multi bay system where the last bay contains both camera modules and monitor modules that bay would use 2010DBVL 00 module In a fourteen bay system the last two bays are monitor bays and would use the 2010DB 00 Module not the 2010DBVL LEVEL 3 192 X 48 Three Bay System A three bay Level 3 Systems allows a maximum of 192 video inputs switched to a maximum 48 video outputs Bay one consists of 192 video inputs switched to video outputs 1 16 bay two consists of 192 video inputs switched to video outputs 17 32 and bay 3 consists of 192 video inputs switched to video outputs 33 48 From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 2 modules and four 2024 1 modules inputs 1 192 outputs 1 16 From the rear o
123. r of bay two the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 1 modules for inputs 257 448 and four 2024VOM 1 modules for outputs 1 16 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect Connect a 75 ohm coaxial cable from the DATALINE 1 output on the AD1024 CPU to the DATA IN BNC of Bay 1 Connect a 75 ohm coaxial cable from the DATA OUT BNC of bay 1 to the DATA IN BNC 2010PS rear panel of bay 2 Connect a 75 ohm BNC terminator supplied with the CPU to the Data Out BNC of Bay 2 Video Interconnections The 16 video outputs from bay 1 located on the rear panel of the 2010DB 11 are grouped by fours and identified by the icon Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons See Figure 5 Data Buffer page 4 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the topmost input BNC labeled 1 on the 2024VOM 1 in bay 2 for output 1 matching icon to icon See Appendix Figure A18 Video Interconnections for illustration of these connections Continue in this manner until 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024VOM 1 Proceed to the next group of
124. r outputs 1 to 16 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See Level 2 192 X 32 two bay system Connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 located on the rear panel of the 2010DB 11 are grouped by fours and identified by the icon lt gt On bay 3 each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four BNCs is used for video output connections See Figure 21 Video Output Module page 9 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the top most input BNC labeled 1 for the 2024VOM 1 in bay 3 for output 1 matching icon to icon lt gt 29 SYSTEM CONFIGURATIONS Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 1 Proceed to the next group of four BNCs on the 2010DB 11 of the first bay and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to the 2024VOM 1 modules Connect bay 2 in a similar manner to the 2024 VOM 1 modules of bay 3 for video outputs 17 32 matching icon to icon lt gt See Appendix Figure A18 Video Interconnections for
125. r outputs 5 8 etc See Figure 21 page 9 Video Output Module Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024VOM 1 in bay 7 for output 1 matching icon to icon lt gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 1 Proceed to the next group of four on the 2010DB 11 of the first bay and connect these four to the second 2024 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to the 2024 18 for outputs 1 16 Connect bay 3 in a similar manner to the 2024VOM 1s of bay 7 for video outputs 17 32 matching icon to icon lt gt Connect bay 5 in a similar manner to the 2024VOM 1s of bay 7 for video outputs 33 48 matching icon to icon lt gt Connect the topmost BNC from bay 2 on the 2010DB 21 panel numbered 1 to 2024VOM 1 in bay 7 for output 1 matching icon to icon Z amp Continue in this manner until connections 1 4 of the 2010DB 12 panel are connected to inputs 1 4 of the 2024VOM 1 Proceed to the next group of four BNCs on the 2010DB 12 and connect these four to the second 2024V OM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 12 panel are connected to 2024VOM 15 for outputs 1 16 Connect bay 4 in a similar manner to the 2024VOM 1s of bay 7 for video outputs 17
126. red in each camera bay for each block of 256 cameras The first camera bay would use a 2010DB VL 11 the second bay 2010DBVL 21 the third bay 2010DBVL 31 and the fourth bay a 2010DBVL 41 In a multi bay system where the last bay contains both camera modules and monitor modules that bay would use a 2010DBVL 00 module In a five bay system the fifth bay is exclusively a monitor bay and would require the 2010DB 00 Module not the 2010DBVL 00 20 LEVEL 1 256 X 16 One Bay System with no Titles A one bay Level 1 system without VOM modules for video titles allows a maximum of 256 video inputs switched to a maximum of 16 video outputs This system does not contain 2024VOM modules From the rear of the bay the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 01 with 16 for untitled video outputs followed by one to sixteen 2016AVIM modules Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect Connect a 75 ohm coaxial cable from the DATA LINE 1 output on the AD1024 CPU to the Data IN BNC on the 2010PS rear panel Connect a 75 ohm BNC terminator supplied with the CPU to the Data Out BNC on Power Supply rear panel Video Input Connections The 2016AVIM is identified with the camera input icon The starting cam
127. rom the bottom four BNC s on each 2024 module must be terminated in 75 ohms Setup Switches The 2024MDT module PCB card contains jumpers that are set to identify the monitors that the video output is being directed to These are factory set for monitors one two three and four 10 Oc Oc D Figure 23 2024 Panel 4 channels looping inputs 4 channels outputs INSTALLATION Mounting Bays are manufactured for standard 19 inch rack mounting and have a rack height of 10 1 2 inches or one rack wide by 6 racks high Bays must be installed with a minimum of 1 3 4 inch clearance between each bay one rack unit It is the responsibility of the installer to insure proper airflow around the bays to provide adequate ventilation In multiple bay configurations identify the various bays carefully before mounting In all multiple bay systems place the video inputs near the top of the racks Power Sources System model AD1024R is configured for use with a 120VAC 50 60 Hz primary power source Model ADS1024RX is configured for a 230VAC 50 60 Hz primary power source 120 V units are supplied with a pendant 3 wire cord and plug for mating to the primary source outlet All 230 V units are supplied with a Euro style IEC type inlet A suitable detachable cord should be connected between the IEC 320 inlet and the power source The cord should conform to all nat
128. s See Figure 21 Video Output Module page 9 24 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the topmost input BNC labeled 1 on the 2024VOM 1 of bay 4 for output 1 matching icon to icon lt gt Continue in this manner until 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024VOM 1 Proceed to the next group of four BNCs on the 2010DB 11 of the first bay Connect these four to the second 2024 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to all of the 2024 1 modules Connect bay 2 in a similar manner to the 2024VOM 1 modules of bay 4 for video outputs 1 16 matching icon to icon Connect bay 3 in a similar manner to the 2024VOM 1 modules of bay 4 for video outputs 1 16 matching icon to icon it See Appendix Figure A18 Video Interconnections for illustration of these connections If there are less than four 2024VOM 1s in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See Level 1 448 X 16 Two Bay System and connect in a similar manner Video Output Connections See Level 1 448 X 16 Two Bay System and connect in a similar manner In the Appendix see Figure A5 Level 1 960 X 16 Four Bay System LEVEL 1 1024 16 Five Bay System A five bay Level 1 system allows maximum of 1024 video
129. s 1 32 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 2 192 X 32 Two Bay System and connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 bay 2 bay 3 and bay 5 bay 6 and bay 7 located on the rear panel of the 2010DB 11 2010DB 12 2010DB 21 2010DB 22 2010DB 31 and 2010DB 32 it are grouped by fours and identified by their icons Each 2024VOM 2 is similarly grouped with four sections of four BNCs with identifying icons A fifth section of four BNCs in the lower left corner is used for video outputs The left most 2024 2 module is assigned to outputs 1 4 the next for outputs 5 8 etc See Figure 22 Video Output Module page 9 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024 2 in bay 9 for output 1 matching icon to icon lt gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 2 Proceed to the next group of four on the 2010DB 11 and connect these to the second 2024VOM 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to the 2024VOM 2 modules for outputs 1 16 Connect bay 5 in a similar manner to the 2024
130. s for outputs 1 16 Connect bay 5 in a similar manner to the 2024VOM 2s in bay 13 for video outputs 17 32 matching icon to icon lt gt Connect the topmost BNC from bay 2 on the 2010DB 21 panel numbered 1 to the 2024VOM 2 in bay 13 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 21 panel are connected to inputs 1 4 of the 2024 2 Proceed to the next group of four on the 2010DB 21 and connect these to the second 2024 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 21 panel are connected to 2024VOM 2s for outputs 1 16 Connect bay 6 in a similar manner to the 2024 28 in bay 13 for video outputs 17 32 matching icon to icon Connect the topmost BNC from bay 3 on the 2010DB 31 panel numbered 1 to the 2024VOM 2 in bay 13 for output 1 matching icon to icon Continue in this manner until connections 1 4 of the 2010DB 31 panel are connected to inputs 1 4 of the 2024 2 Proceed to the next group of four on the 2010DB 31 and connect these to the second 2024 2 for outputs 5 8 Continue in this manner until all 16 connections of the2010DB 31 panel are connected to the 2024VOM 2s for outputs 1 16 Connect bay 7 in a similar manner to the 2024VOM 2s in bay 13 for video outputs 17 32 matching icon to icon Connect the top most from bay 4 on the 2010DB 41 panel numbered 1 to t
131. s than eight 2024VOM 1 modules in the system the remaining BNCs on the 2010DR XX do not require any connection Video Input Connections See LEVEL 2 192 X 32 Two Bay System and connect in a similar manner Video Output Connections See LEVEL 2 192 X 32 Two Bay System and connect in a similar manner In the Appendix see Figure A9 448 X 32 Four Bay System 2010DB 12 are grouped by fours and identified by the icon gt Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four BNCs is used for video output connections See Figure 21 Video Output Module page 9 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the topmost input BNC labeled 1 for the 2024VOM 1 in bay 2 for output 1 matching icon to icon lt gt 30 LEVEL 2 704 X 32 Six Bay System A six bay Level 2 system allows a maximum of 704 video inputs switched to a maximum 32 video outputs Bays one and two each consist of 256 video inputs Bay three consists of 192 video inputs with the first group of 16 video outputs Bays four and five also each consist of 256 video inputs Bay six consists of 192 video inputs with the second group 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 11 with 16 BNCs for conne
132. st 2024VOM 1 module is assigned to outputs 1 4 the next for outputs 5 8 etc See Figure 21 Video Output Module page 9 Using high grade RG 59U video cables connect the topmost BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024VOM 1 in bay 4 for output 1 matching icon to icon gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 1 Proceed to the next group of four BNCs on the 2010DB 11 of the first bay and connect these four to the second 2024 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to the 2024 15 for outputs 1 16 Connect the topmost BNC from bay 2 on the 2010DB 12 panel numbered 17 to the 2024VOM 1 in bay 4 for output 17 matching icon to icon gt Continue in this manner until connections 17 20 of the 2010DB 12 panel are connected to inputs 17 20 of the fifth 2024VOM 1 Proceed to the next group of four on the 2010DB 12 of the second bay and connect these four to the sixth 2024VOM 1 for outputs 21 24 Continue in this manner until all 16 connections of the 2010DB 12 panel are connected to the 2024VOM 1s for outputs 17 32 Connect the topmost BNC from bay 3 on the 2010DB 13 panel numbered 33 to 2024VOM 1 in bay 4 for output 33 matching icon to icon gt Continue in this manner until connections 33 36 of the 2010DB 13 panel are connec
133. ted to inputs 33 36 of the ninth 2024VOM 1 Proceed to the next group of four BNCs on the 2010DB 13 of the third bay and connect these four to the tenth 2024VOM 1 for outputs 37 40 Continue in this manner until all 16 connections of the 2010DB 13 panel are connected to the 2024VOM 1s for outputs 33 48 See Appendix Figure A18 Video Interconnections for illustration of these connections If there are less than twelve 2024 VOM 1s in the system the remaining BNCs on the 2010DB XX do not require any connection Video Input Connections See LEVEL 3 192 X 48 Three Bay System and connect all bays in a similar manner Video Output Connections See LEVEL 3 192 X 48 Three Bay System and connect all bays in a similar manner In the Appendix see Figure A13 256 X 48 Four Bay System SYSTEM CONFIGURATIONS LEVEL 3 448 X 48 Six Bay System A six bay Level 3 systems allows a maximum of 448 video inputs switched to a maximum 48 video outputs Bay one consists of 256 video inputs bay two consists of 192 video inputs with the first group 16 video outputs bay three consists of 256 video inputs bay four consists of 192 video inputs with the second group 16 video outputs bay five consists of 256 video inputs bay six consists of 192 video inputs with the third group 16 video outputs From the rear of bay one the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is
134. that contain buffered video outputs for monitors 17 through 31 would use a 2010DBVL 12 a 2010DBVL 22 a 2010DBVL 32 and a 2010DBVL 42 for each respective group of 256 cameras In a system that includes Condensed bays the Condensed bay that contains outputs 17 to 31 would use the 2010DBVL 00 Module In a multi bay system where the last bay contains both camera modules and monitor modules that bay would use a 2010DBVL 00 module Any bay that contains only monitor modules uses 2010DB not the 2010DBVL Module LEVEL 2 64 X 32 One Bay System The single bay Level 2 system uses one 2020R matrix Condensed bay From the rear of the bay the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by one to four 2016AVIM 2 modules and one to four 2024VOM 1 modules for outputs 17 to 32 The next modules to the left are the one to four 2016AVIM 3 modules followed by the one to four 2024 1 modules for outputs 1 to 16 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect Connect a 75 ohm coaxial cable from the DATALINE 1 output on the AD1024 CPU to the Data IN BNC on the 2010 5 rear panel Connect a 75 ohm BNC terminator supplied with the CPU to the Data Out BNC on Power Supply rear panel Video Input Connections The 2016A
135. the following manner the far right module is the 2010PS the next module is the 2010DB 13 with 16 BNCs for connection to the 2024VOM 2 modules in bay fourteen followed by sixteen 2016AVIM 4 modules inputs 1 256 From the rear of bay ten the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 23 with 16 BNCs for connection to the 2024VOM 2 modules in bay fourteen followed by sixteen 2016AVIM 4 modules inputs 257 512 From the rear of bay eleven the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 33 with 16 for connection to the 2024VOM 2 modules in bay fourteen followed by sixteen 2016AVIM 4 modules inputs 513 768 From the rear of bay twelve the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 43 with 16 BNCs for connection to the 2024VOM 2 modules in bay fourteen followed by sixteen 2016AVIM 4 modules inputs 769 1024 From the rear of bay thirteen the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by eight 2024VOM 2 modules installed left to right outputs 1 32 From the rear of bay fourteen the modules are installed at the factory in the following manner the far right module is the 2010 5 the
136. tput will be adjusted The H V and B pushbuttons are used to adjust the desired setting See Figure 29 for location of these controls The video output title to be controlled is selected from the rotary switch labeled A D To select the first video output turn the rotary switch to position A To select the second video output for title adjustment move the rotary switch clockwise one position Proceed in this manner for the final two video outputs After selecting one of the four outputs press the H pushbutton The title shifts to the right until the pushbutton is released Note If the pushbutton is not released the title will reach an end point and return to the left most position and begin to shift to the right again After the proper horizontal position has been selected depress the V pushbutton The title will shift downward until the pushbutton is released Note If the pushbutton is not released the title will reach the bottom of the screen as defined by the vertical sync move to the top of the screen and begin to shift down again After the proper horizontal and vertical positions have been selected proceed to the brightness control The characters of the title are white with a black border This enhances visibility under varying light conditions The brightness control provides eight steps of white levels to change the characters from white to black To change the brightness of the titles depress the B
137. wed by four 2024VOM 2 modules for outputs 1 16 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See LEVEL 1 448 X 16 two bay system and connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 through 4 are located on the rear panel of the 2010DB 11 lt gt 2 ze 31 and 41 respectively They are grouped by fours and identified by their icons Each 2024 2 is similarly grouped with four sections of four BNCs with identifying icons A fifth section of four BNCs in the lower left corner is used for video outputs The left most 2024VOM 2 module is assigned to outputs 1 4 the next for outputs 5 8 etc See Figure 22 Video Output Module page 9 25 SYSTEM CONFIGURATIONS Using high grade RG 59U video cables connect the top most BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024 2 in bay 5 for output 1 matching icon to icon 8 Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 2 Proceed to the next group of four on the 2010DB 11 and connect these to the second 2024 2 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to the 2024VOM 2s for outputs 1 16 Connect the top m
138. wing manner the far right module is the 2010PS the next module is the 2010DB 12 with 16 for connection to the 2024VOM 1 modules in bay four followed by sixteen 2016AVIM 3 modules inputs 1 256 From the rear of bay four the modules are installed at the factory in the following manner the far right module is the 2010PS the next module is the 2010DB 00 followed by twelve 2016AVIM 3 modules for inputs 257 448 and four 2024VOM 1 modules for outputs 17 32 Smaller matrices such as those ordered with future expansion in mind may have fewer modules installed IDENTIFY THESE MODULES CAREFULLY BEFORE PROCEEDING Data Interconnect See Level 2 192 X 32 two bay system Connect all bays in a similar manner Video Interconnections The 16 video outputs from bay 1 and bay 3 located on the rear panel of the 2010DB 11 and Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024VOM 1 Proceed to the next group of four on the 2010DB 11 of the first bay and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to all of the 2024VOM 1 modules Connect bay 3 in a similar manner to the 2024VOM 1 modules of bay 4 for video outputs 17 32 matching icon to icon See Appendix Figure A18 Video Interconnections for illustration of these connections If there are les
139. wing separate units may be connected to the AD1024 system for added capabilities For specific information refer to the respective data sheets 2091 Control Code Generator Distributor The 2091 provides 64 control code outputs for control of 1640 and 1680 Series Receivers actuating pan tilt lens zoom focus and iris and auxiliaries at suitably equipped camera sites 2031 Switcher Follower 2032 Alarm Responder 2033 Auxiliary Follower The 2030 Series Followers switch external circuits when designated cameras are called to designated monitors 2031 when designated monitors are in alarm conditions 2032 or when designated auxiliaries are called up or designated cameras are alarmed 2033 ADULP Looping Panel The ADULP Looping Panel is used to facilitate the looping of video signals for the AD1024 system from external inputs or to external devices such as time lapse video recorders switchers monitors etc Other Switcher Control System Accessories 1640 and 1680 Series Receivers 1670 and 2078 Series Keyboards 1680MG Manchester Generator 1683 Control Code PSK Modem 1981 Port Expander 2081 Port Expander 1983 Code Converter 2083 Code Translators 2096 Alarm Interface Unit 1985A Hot Switch IF YOU ENCOUNTER ANY PROBLEMS OPERATING THIS UNIT OR NEED ASSISTANCE CALL OUR TECHNICAL SUPPORT CENTER AT within the United States 1 800 442 2225 outside the United States 845 624 7600 This installation should be made
140. x x X x cooo 385 400 401 416 417 432 433 448 449 464 465 480 481 496 497 512 DAOA oon cooo X X x cooo 513 528 529 544 545 560 561 576 577 592 593 608 609 624 625 640 641 656 657 672 673 688 on on oon X X x PAPA x 689 704 705 720 721 736 737 752 753 768 oon X X x X X x x X x 769 784 785 800 801 816 817 832 833 848 849 864 865 880 881 896 897 912 oon 913 928 929 944 945 960 961 976 977 992 993 1008 1009 1024 15 5 Video Output Module Switches The 2024VOM Video Output Module adds character information in the form of titles and time and date to switched video from 2016AVIM modules Each 2024VOM card contains 2 pin jumpers and one 8 position DIP switch see Figure 28 These are set with the module removed from the bay Four 2 pin jumpers for setting monitor identificat
141. y They are grouped by fours and identified by their icons Each 2024VOM 1 is similarly grouped with three sections of four BNCs with identifying icons A fourth section of four is used for video output connections The left most 2024VOM 1 module is assigned to outputs 1 4 the next for outputs 5 8 etc See Figure 21 Video Output Module page 9 Using high grade RG 59U video cables connect the top most BNC from bay 1 on the 2010DB 11 panel numbered 1 to the 2024 1 in bay 4 for output 1 matching icon to icon lt gt Continue in this manner until connections 1 4 of the 2010DB 11 panel are connected to inputs 1 4 of the first 2024 1 of bay 4 Proceed to the next group of four BNCs on the 2010DB 11 of the first bay and connect these four to the second 2024VOM 1 for outputs 5 8 Continue in this manner until all 16 connections of the 2010DB 11 panel are connected to the 2024 1 modules Connect bay 5 in a similar manner to the 2024VOM 1s of bay 8 for video outputs 17 32 matching icon to icon lt gt Connect bay 9 in a similar manner to the 2024VOM 1s of bay 12 for video outputs 33 48 matching icon to icon lt gt Connect the topmost BNC from bay 2 on the 2010DB 21 panel numbered 1 to 2024 1 in bay 4 for output 1 matching icon to icon gt Continue in this manner until connections 1 4 of the 2010DB 21 panel are connected to inputs 1 4 of the 2024VOM 1 of bay 4 Proceed to the
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