MTPCI-DD OM
Contents
1. 20 2 20 1 1 4074 0000 OU 320 0 0 0 33MHzQ 133 250 000000 UHUOOUOUUUOUUNOON 18 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 000 0000000 D UD 50 00000000000 00 D DD 0 5 Dupguupugpupdagdgagidbliulu eswe wewo emro sso awost _ svewor svcmoo stawoa STawoi strubo 8H SR 03 EHCKSI EHCKSO STCKSO sh sm oirrsm HVPOL 00000 000000 5 ooo ____ 07 06 jos p3 o fom 00 58 00 cmpmo 1 CMR SR 00 CMRMD on p n 00 19 2000000 000 00000 0 gagggugagpna upnapnapnanu 0000 gunuanugnuangugnauanud2and 100000 SONY 7500 8500 NEC TI 150A CMDMD A48 0000600 00 0 00000 0 80 00 0 0 0 0 0 0 00 00 00 00 0 1000002. L1 L1 L1 L1 L1 0000000000 000000 000000000000 000 D gpnadnpadn utdno o Dugnaudpanpnu 000000 EXE o c3 ojo ajojo gala 0 0000000000 000000 000000000000 D gpupnpna aagapuanu 000 0000000000 oja ojo pg 0 OMOOUO0000U0000 000000 O oO 0A000000 000000000 0000000000 000000000000 00000000 0000000000 00000000 0000 00000 1 ojojo a ojojo alojo a c3 L3 c3 oja o oO 11 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 OOO 0000000 00000 O 5MHzq 40MHz 0 D 63kHzD 00000000 24 545AMHz 12 2727 2 8 18MHz 6 14MHz 24 5454MHz 19 40 00000 e AMPOOOOOUOUN 800000000000000 40 2 0000
3. 3 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 About the guarantee Guarantee period depends on the prescription of our company The guarantee period of the gratuitous repair is 1 year in principle The carriageis a user burden Even if it is a gratuitous period the repair in location becomes onerous It becomes an onerous repair in the case of the malfunction that originates from the responsibility of the user even if it is a gratuitous period In the casethat the user did reconstruction repair tothis product it becomes onerous In the case of the repair the gratuitous repair is in the case of the malfunction of the same part In this case the half year is a gratuitous period Even if it is guarantee period inside the case that there is not user registration it becomes an onerous repair 0000000
4. 0o00 DO0000000000000000000000000000000000000 Oo L3 pr L3 pr On Oo L1 r3 lt O gt 8 116 Microtechnica Doc No MTPCI DD V1 01 Date 1 May 2003 Rev 1 01 D 34 O0O00000000 00 0 0 DD SI1 150 0000 IQ E oo i oo o oo o n o0 EXT i oo 9 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 D uuu 000 000000 000000000 0000 1 750000 000 000 0 Vpp 00000000 000000 1KHz0 60KHz 000000 194 10020 0000 0 DSUB 15P 000 000000 0000 osuB3e _____ 0000000 0000 _ ______ 10 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 000 00000000000
5. 000 8 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Repair request 0000 MICROTECHNICA Co Ltd Maintenance department of Turugashimajigyousho 000 TEL 000 000 0000 FAX 000 000 0000 HB phttp www microtechnica co jp Destination Turugashimajigyousho 5 12 1 Suneori chou Turugashima shi Saitama ken 350 2211 J apan MICROTECHNICA Co Ltd Maintenance department of Turugashimajigyousho 000 0000 000 0000 00000000000 00 0 bm en 000000 000 http www microtechnica co jp ll unt 000000 Address Return address of the repair article Payment method Company name Executive Assignment coe Name co dmm ______ pom _ _ 4 00000 Bank payment 0 0 0 L Purchase store Company name 000 Telephone Fax Malfunction contents symptoms T 00 0 0 o 0000 Repair contents 0000 9 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Contents Outline ete O Characteristic Constitution of the Board 3 1 Connection with the camera et 3 2 Connection with the monitor 0000 10 E 0 Specification of hardware 4 1 Input vide
6. 2000 00 oO oo 4 80 1410 0 0 000000 D UU 000000 00000 00000 O0 OUT 1 Lr 0 4H 0 0 0 0 0 0 EE Ey 31 116 Microtechnica Data volume A List of the command 0000 2D B Example of setting 0000 20 1 Example of the to camera 1 20 Video signal of the EIA standard 00 O 20 Camera of 00 20 Camera of NECO O00 2 D CameraofJAID D 0O 2 D Camera of TELID OQ 20 Camera of the Takenaka system 0 0 0 2 D B 2 Example of the setting to a monitor 1 VGA monitor 2 Setting of superimpose B 3 Example of the setting to DMA forwarding 1 I mage catch by DMA forwarding 2 Forwarding to the buffer memory for the monitor by DMA forwarding 1 116 Microtechnica Data I A List of the command Commandregiste 1 Port IN Byte X Statusregste input output bit of wide use 10 Word em pest qu The line counter for
7. GETMC GMMD GMsLO 0 30000000 YNBW VUBWOOOOOOCOO 000000000 0 OVMD 1 1 25 175MHz VGA 640x480 0 0 0 4000 000000 2 40 4 SVGA 800x600 0 0 0 6360 000000 3 65MH 2 XGA 1024x768 0 0 0 10321 000000 OOOO VGA_S 0000000000 OVMD gt 00000 0 0000000000000 000 0000600 0000000000 00 0000 1 640 480 31 5KHz 8000 0 0 U OCA 800 2 SVGA 800x600 37 9KHz 10569 0 0 0 OCA 1056 3 XGA 1024x768 47 8KHz 13600 00 0 1360 O UNBW OUBWI 1 1 00000000 000000000000000000 0000000 27 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev
8. 00000 SMOD0OD 7 7 000000 000 1000000 0 00000000 5420 000 0 20 340000000 201 00000 OU Da ennpnpnpnpnpnpnp 28 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 00 HD A D uuu D D AD 1 VD A 0000 D 0 D AD 21 STRG A 000000000 D 0 D AD 30 5 UUOOUUUUUO OO0 80 40 HD B D uu D D B0 50 VD B D uu D D B0 60 GTRG B D uuu D D B0 70 GTRG A D uuu D D AD 20000000 5 000 0000 00000000000000 0000000 00001 N8040000000000000 HD 0000 20000000 5 vopwo 0000 0 15 0000 VDD 00000000 INB7 GTRG A 0 0 0 HOOO00O0O0OC
9. 4 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 1 Confirmation of the delivery commodity 58 06000000 Accessories of this product confirm whether they are all together Board main 1 0000 MTPCI DD 1 sheet CD ROM of the belonging 0 CD ROM 1 sheet Contents of CD ROM CD ROM 00 6 1 Driver program for os win 2000 win 95 win NTOLTI E E D E D D I E D 2 Library program of the DMA board and VC VB Sample program Sauce listing and EXE form Camera set program 00000000000 3 Document OperationM anual T 0 00 0 LIE nglish edition J apanese version File of the explanation book regarding camera setting 0000000000000 nly the apanese versioni Library specifications 00 000000 Only theJ apanese version VB sample program manual T B 000000000000 Only the J apanese version VC sample program 000000000000 the J apanese version 2 Introduction of camera cable the different sale 0 0000000000 0 0 The cameras of various makers are able to connect to this product The pin number of the connector that an input output signal is connected may differ by the camera Thereis the fear that damages it if it does not connect the camera and this product correctly The cable of the exclusi
10. 0000 DU D Uu ESI E DMADOOOOUO 30000 40 0 0000 00 0 0000 0 0 20 0 0 00000 000 80000 000004000 40 00000000000 31 24 23 16 15 87 0 000 00 D70 Do 000 10 D150 D8 00020 0230 016 00030 0310 024 000000 DMAQ 0 0 10241 0 0 20480 0 0 00 00 0 0 0 0 00000 00 0 00000 10 00 10240 O O 20480 p 0 20480 30 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 000 00000 0 57000 00000 00000 0 000 ooo __ 1 0 015 00 000 00000000 32000000000 00009 32000 00000 0000 10 4 000 00 0000 00000000 0000 0 000 OOUOUOUUUCUO 000 ____ 7 joe 05 ffs gt fT 0000010000000 0000000 000000000 og 1
11. 32000000 000000000000 90 D uuu 80000 0000 CONFIGURATION EEPROM DATA 000 00000 00H 4444 4054 0680 0000 0000 0100 0000 0000 10H 0000 0000 FFFF FFE1 0010 0001 0020 0000 20H 0000 0000 0000 0000 0000 0000 4201 0041 30H 0000 0000 0000 0000 0000 0000 0000 0000 40H 0000 0000 4444 4D54 0000 0000 0000 0000 50H 0000 0000 0000 0000 o poa __ 5 PCIBARO PCI D UD 0000000000000 2 PCIBAR1 PCI J D UD 000000000000 PCIBAR2 00000 2cH oon SubsystemDevcdD VendelD _ A444D54 1 25 rl a 3cH uo 000 Gntant 000 40544 MN0 00000000 PCI 4 20 0000000 4444H 00000 0 0 D D Pci s0800 D0000000000000000000000000 ODO0000000000000 00 PCIBAROD TOL D 00 00 00 0000 OOO 00001 00000000000 0000 0 0000 0 00000 000 OO 0 000000000000000000 90 10000 0 000 0 0000 00 14 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 UUOOUUUNUO PCI 9080 oooo jio
12. 2 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Mode register SR 00 00 One line output camera Condition 1 Two line output camera settingof CMDMD camera A or camera B DONNE FC EHE SR 01 00 Normal scan 10 Random scan Mode SYCMDI1 0 O external H V l external H setting of a Synchronous mode 2 internal C 3 internal HV camera 1786 2 TRG VD 3 VD TRG 4 TRG TRG SR 02 0 The 1st field Setting of 1 Field immediately after triggering a clock 0 49 0909 2 LVCO 62 937KHz VCA Resource clock Input clock CLKDV1 0 0 1 1 1 1 2 2 1 3 3 1 4 CCKDV1 0 0 1 1 1 1 2 2 1 4 3 1 8 Camera clock EHCKS1 0 0 12M 1 6 2 3 3 1 5M Clock for HD VD detection LVD 2440 SQ52KHz 3 Direction of the signal SR 06 SPOL 7 0 O Positivelogic 1 Negative logic hu ee Signal mode SR 08 OVMD S 1 VGA Output mode Setting of monitor OITRSM 0 Non interlace 1 2 1interlace Scanning mode HVPOL 0 Negative logic 1 Positive logic Polarity of a synchronous signal 3 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 B Example of setting B 1 Example of the setting to a camera The condition such as the selection of the input method the synchronization with a camera the kind of camera set to this board It is able to set up it easily when the program of attachment is used
13. sR 18 HDSCO 1200 00 0110 000 T 0D0000000000000000000M00000000000000000 000000000000000000000000000000000000 000000000000 000000 SR 1C TRGWwW000000000000000000 1000 00 D90 00000 0000000 62 937K H z 49 0909 H z 780 25 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 OOO 00000000000 SR 30 3B Dugpununupnnununnaunuauanupnpnunaugpnado veAn nnd DuggnpnugugpnuuuapnnununnaugupnpnaugdgpnpnadpReBlH nnl 00000000 cH SRIHD O 56 sR 30 ocap000000000000000000000 0000 0070000000000 VGA 0000000000 6293KHz x _5 _5 vcopo000000000000 00 10M0 75 21 0000000 1600 11900 00000000 0D0
14. 000 0 0 Lp dT 3 116 Microtechnica Doc No MTPCI DD OM E V1 01 o N gt Ore gt c c 5 gt ac r3 r3 r3 r3 r3 mm r3 r3 r3 r3 r3 r3 um r3 oO oo oO L3 mm oO r3 Ez oo r3 r3 Oo r3 r3 r3 oo r3 fed r3 r3 r3 oo r3 r3 oO r3 oO oO oo N oO Cl L3 EX EYES ON I Og o go mm oo r3 Og L3 r3 r3 Ooo Ooo r3 Og L3 r3 r3 Oooo r3 L3 5 Lr r3 Ez oOo Ooo r3 Og L3 r3 r3 EHE Ooo r3 Ez Oy 22 r3 E pr r3 r3 Ooo E r3 E cm oO L3 4 r3 r3 220 oO Et et ooo mo Lr Zumprmtuuu o r3 oOo Ooo r3 r3 05 r3 Oooo Ooo r3 r3 r3 r3 r3 Oooo oO oO 1
15. 0 Oooo OO E HVPOL 000000 dd 000000000 5 000 00000 00000 5 0 0000000000 5000000000000 000000000000000 24 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 OOO 00000000000 SR 10 1C ELI IST al cs cH _____585 580 _____ SRO SR 10 nu 10000 0 090 000 0000000 62937 2 x 00000000 10 75 1 000 1600 10230 00000000 sR 14 UNBPO0O00000000000000000000 900 00 080 Dor 0000000000000000000000000000000 20000 0000000000000000000 snas unswgo000000000000000 00000 200000110 00000000 tm 1 4 snae 7 D00 000000000000000 UM
16. 000000000000000000 0012 _ 0018 0014 000000000 1 12 20 1 4 30 1 8 DODD 00000000000000000000 0000000000 21 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 1 12 2727 409000000000 1 000000000000000000000000000000 D B uultu 49 0909M Hz 24 5454MHz 12 2727MHz MQCKS CLKSEL CLKDV1 0 2 14 318 2 0 0 00 54 0000000000000000000000 7680 0000 00000 3 102277 0 000 00000 00 0000 51000000000000 00000000 4 20MHz 19 9825 20 00 00000000 5 20 245MHz 20 234MHZ UV 00000000000000000600 CLKSEL VCO 643 62 937K Hzx 643240 468MHz 40 468M Hz 2 20 234Hz lt O gt CLKDV1 0 MQCKS CLKSEL e CLKDV1 0 VCO VCO 2 31 469K Hz 31 469K Hzx 643 20 234M Hz 20 234M 2 1 20 234 Hz mocks ___ 1 ____ pcukseL fji ____ 22 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 00000 0000000 0 5 3 000 ____ 07 __ 06 105 foa os So 1 0 Jsrcks srckso 012M _ 16 _ 23MINRM _ 315M EHCKS1 0 2 3M NRM HDVDO D D 000 000 400 60 2 0
17. oO L3 r3 rr Ooo r3 r3 2 lt L3 Ooo oO oO O Oooo Ooo r3 r3 O 0A gt Oooo Ooo r3 r3 r3 El Ez Ooo Ee r3 r3 Oooo Ooo r3 r3 r3 E Er L3 EJ r3 r r3 r3 Oooo p4 EJ r3 r r3 oo Ooo 5 9 Ez L3 p4 52 rr Es Ooo roe oo es EET EJ r r r3 Oo El Oooo r3 2 Ooo L3 r3 rr p4 EJ r4 r r3 Ooo L3 r3 rr p4 EJ F3 r r3 L3 p4 E3 EJ F3 F3 C3 FH d Oooo L3 E3 EJ EJ F3 F3 V EJ EJ F3 3 Oooo fg ec gt Oooo Ed Ed Ed Ed Ed Ed EJ EJ EJ EJ EJ r3 Oooo o nooo 9 9 Oo r3 Ooo r3 51 r3 r3 4 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 D uuu 000 0000000 o 5 15 3 e 5 VGA DSU B 15P
18. 1 Shutter control dock STCKS 0 HD 63 551 S OUTBOisthe HD signal BIOMDO 1 Output signal Negative logic output SR05 07H SPOLO 1 Negative logic SR06 87H SMOD1 1 Camera use OUTB1istheVD signal SRO7 87H BIOMD1 1 Output signal Negative logic output SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 istheTRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic SMOD2 1 Camera use INB7 isthe external BIOMD7 0 Input signal signal Negative logic SPOL 7 1 Negative logic IN put SMOD7 1 Camera use The shutter time is able to be controlled with the pulse width of a trigger signal if the switch of a camera is set up to the pulse control mode Exposure time Shutter clock HD 31 8u S x TRGW value For example if it is 1mS 1 1000S HD231 8p S TRGW 12 then exposure time is 0 985mS The shutter time is set up with the rotary switch of a camera The width of the 31 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 trigger signal does not take part in shutter time The VD signal is produced after a trigger signal and the data is catch Therefore you need to delay VD start only the period in shutter time This delay is abletoadjust it with the width of the trigger signal For example if it is TRGW 128 80H then delay time is 4mS 1 250S The setting value is half if the shutter time becomes to half The shutter time is able to controlled with the
19. gt cec cc cce m st uw mw n m m nm s 000r nq umomssrinrooo c c ce c rnm c n n n c ce ce c ce CN CN CN CN CN CN CN CN CN NAMAM oOo L3 r3 L3 C3 E3 E3 EJ C3 C3 C3 L3 E3 C3 EJ EJ EJ EJ EJ F3 C3 C3 EJ oo L3 r3 L3 E3 E3 EJ C3 CJ L3 E3 E3 EJ C3 EJ EJ E3 EJ EJ F3 C3 C3 C3 oOo L3 r3 L3 C3 E3 E3 EJ C3 C3 CJ L3 E3 E3 E3 C3 EJ F3 EJ EJ EJ F3 C3 C3 F3 oo L3 r3 L3 C3 E3 E3 EJ C3 C3 CJ L3 E3 E3 E3 C3 EJ EJ E3 EJ EJ F3 C3 C3 C3 L3 L3 L3 L3 oO L3 L3 oo L3 L3 L3 L3 oo L3 noo oO oo oo r3 Oo ol ooo oo E 23 oo L3 r3 L3 r3 L3 C3 E3 E3 E31 0 p p oo oo noo L3 oo o oo L3 r3 L3 F3 E3 C3 F3 C3 O L3 L3 F3 C3 F3 F3 EJ C3 F3 FJ p p o oo L3 L3 E3 E3 EJ EJ E3 EJ EJ C3 F3 p4 E3 EJ EJ EJ EJ EJ EJ EJ EJ p p p o o O L3 E3 EJ EJ C3 EJ C3 EJ C3 F3 p4 E3 EJ E3 EJ EJ EJ EJ EJ EJ p p p p o O L3 E3 EJ EJ E3 EJ F3 EJ C3 ESTEE Ed F3 o ES L3 E3 EJ EJ E3 EJ C3 EJ 00o 2020 0 L3 CJ Ed E3 Ed Ed EJ E3 E3 EJ E3 F3 EJ EJ EJ F3 EJ FJ p4 5 ao oO L3 oo r3 pm rpm 5 5 L3 EJ E3 E3 E3 EJ E3 EJ EJ E3 EJ EJ EJ EJ EJ E3 EJ EJ E3 C3 E EJ EJ EJ E3 EJ EJ F3 O C3 L3 L3 F3 E3 EJ EJ E3 EJ EJ E3
20. 0 0020 0 0 STR 0000000 2 0 0 0 0 2 0 0 20 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 00000 0000000 0 2 000 ___ 07 06 05 foa os jp foo 02 itrsm irRGM mocks ctkseL cLKpvo cckpvo SR 02 ITRSM 0000000000 0021 0000000 00000 00000 Dp gBBappna agBaBDaHBBaDD 00 ITRGM nnun annannannannn nn nn nvnnnnnun n nnnn nn 00000000000000100000 0 00000000 000000000000 033ms0000000 DO0000000000000000000000000 o000000000000000000000 00 000000000000000000000000 0000000000 000000000 FLDG 1200000000000 00000 000002 5 00 49 0909 2 O0 0 VCO 62 937KHzx VCA 00000 0000000 49 0 00000000 MQCKS xy CLKSEL 0 49M Hz 120 24 545MHA 0 00 000 000 00 000 00000 00000 CLKSEL 000000 CLKDV10 000000 CCKDV10 0 0 49 0909MH7 000 000000000000000000 00 0 SYCMD 0 1 9 5Mg 40MMHzn 0000000000000 nnnn nan ecLcaynnn nnn nnn vcannn 00000000000000 00 049M H20 000 000 0 0 vcog 00 00000000000000 CLKSELD 00 000 vconnnnn 0000000000000 5 n 12
21. forwarding SR 0 d Port8 IN _ Progress counter from input 58 24 Port8 _ Progress counter from input SR 25H Select the SR registration ee adl The line counter for DMA forwarding d Port 10 IN Bye ___ Statusregiste B8 Port 14 Pointer dear of the output buffer memory for a monitor Outputprt D7 06 DS foa 03 02 foi oo GETC GMOD DDMD GETMC GMMD GMSL 10H CameaB GETC GMOD oomo l D 21 E Input port D7 06 05 D4 02 14H Clear the pointer of the output buffer memory for a monitor Data be disregard Ouputprt 07 __ 06 Ds fa o2 m oo GTRGA __ imutprt D7 __ 06 DS D4 02 o _ 00 H 8 bit output data Wideuse OUTB7 ouTBS ouTB3 oUTB2 ourB1 OUTBO VDB STRGB STRGA 1 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Pot sR D7 foe D5 D4 02 b CH __ 586 SR5 564 SR3 582 SRI 8H SR OL RNDST SYCMD1 SYCMDO STRMD2 STRMD CCKDV 8H SR 03 EHCKSI EHCKSO STICKS BIOMD1 SPOLI SMOD1
22. 000000 0 BNC A OOUOQOUOO0 BNC B 5 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 D 31 0000 DSUB 15P 000000 000000000 bibonng 0 oja 00 0000 00000 pbpec2zvujinnnnpapnus evgypnppopnuuuuguuaagggggadaduu 5 OO 00 50 15 000 0 7500000000000 pauuggannuugunnuugaggpnguguugg 000000000 000 8 0000000 000000 SONY 550 NEC TI 400 480 1200 1250 0 000000000000 00000 0O DMC BC B0 00000 SONY 5 30 50 70 NEC TI 400 480 1200 1250 0 00000 0 O00000 0 DMC BC D 0000 SONY XC HR300 TELI CS3720 0 00000 0 000000 DMC BC C 0 0000 SONY 75 7500 QQ 000 000 6 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1
23. Camera of TELI Camera of the Takenaka system EI ET EJ Ez Ez E B 2 Example of the setting to monitor 000 VGA monitor 000 Setting of superimpose B 3 Exampleof the setting to DMA forwarding 000 Image catch by DMA forwarding 000 Forwarding to the buffer memory for the monitor by DMA forwarding 11 116 Microtechnica 1 Outline This Operation M anual is describing the hardware explanation with regard to MTPCI DD Y ou incorporate this board to a personal computer of PCI bus installation and use it This board inputs the video signal from a camera and digitizes And it forwards the data tothe system memory in the personal computer by DMA forwarding Also the contents of the output buffer memory that are installed tothis board can be displayed to a VGA monitor 4 boards of this product are ableto be installed to 1 personal computer simultaneously It is possible control this board easily when the driver routine of the boards is used A fundamental library is availableto process the image data that was taken to the memory Please pay attention sothat the forwarding mistake does not result in consideration of the restriction of the forwarding speed of a PCI bus in the case that 4 boards are used simultaneously System configuration example Monochrome CCD camera VGA standard Monochrome monitor CCD camera
24. _ OUT i 94H OUT DMACh1 Local Address DMACh1 Transfer Byte Count DMACh1 Descriptor Pointer DMA Ch Command Status Register 15 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 000000000000000 000 10000 2 0 00 D 16 321 oooo io 00D 0 0 0 un nnn mn IN 000000000 0 04H IN OUT 0000000000 0 MM n E IN IN IN N IN N i oO ojo alo p ojojo O Oo L1 000 0 SR SR 24H 25 57000000 0 000 000 0000 OUT Xx14H OUT 0 g oO Oo Oo Oo Oo Oo L3 Oo L1 oO i Oo L1 oO Hs ___ _ 00 0000 00000000000000000000000000000000000000000 o000000000000000000000000000000000000 00000000 o0000000000000000000000000 000000000 o000000000000000000000000000000000000 D
25. GET 0 0 GTSMD 000000 00 198670 000000000000 STRO 0 0000000000006 0000 6 7 OOINB7JOOOUOUOABOOOOOOUODUOUUODOU0D0UO 19 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 00000 0000000000 SsRal p Jo os a gt p o FRNDST SYCMBI SYCMDO STRMD2 STRMDI STRMDO ugaau tavbl tdt g uugaggpauucerepnpggguupnangnuagagdugpaupna duduo 00000 STRMD2 1 0 0020000 00000000000000000000000000000000000 10STRGO00000000000STRA00000000000000000 0000000SsTRe0000000000000000000000000 0000000000 0TRGW000000 000000000 STRGD 000 0000 05 260 0 00 00 03H00 400 0000 0 0 00 00 00000 000000000000 20 STRGD 00VDO00000000000000000 STRG0OO00VYPO0000000000000000000000000000 000000STRG0000000TRew0000000000000000 u nvbpuunmnnnn srRennn TRewnnnnninnH n Un 3ivbpunnsreannu n ngunnnnnnununn VD000STRAO000000000000000000000000000 000000VY200000000TRCwW00000000000000000 00 STRGOO 00000 0 05 260 00 00 0 00 010 0000 200 5 000 0000 5 00 STRGO 00 5
26. In the case of 1line output camera the example that connected to camera A is shown In the casethat it connects to camera B or 2 cameras the setting on the side of B becomes necessary 1 Video signal of the EIA standard Itisin the casethat only the video signal of a camera is input and is used Camera mode CMRMD 0 One line output camera SROO 00H lunit meo Input video dock MQCKS 0 12 2727MHz CLKSEL CCKDV 0 SROScEDR eso 5 1 0 SRI7 FOH When you output the GETC command 80H after above setting it is input 1 screen 4 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 Camera of SONY 2 1 XC75 camera It is in the case of the random shutter camera for industry Signal that is connected to the board are a video signal a HD signal a VD signal a TRG signal It is used the external synchronous mode The video clock 12 2727M Hz the horizontal frequency 15 734kHz the vertical frequency 30Hz frame 2 1 1 It uses it with a normal mode CMRMD 0 One line output SROO 00H camera 1 unit Camera mode Command mode External trigger mode Shutter mode Synchronous mode Shutter trigger mode Scan mode Catch mode Input video clock Detection clock of SYNC Shutter control clock OUTBOistheHD signal Negative logic output OUTB1istheVD signal Negative logic output OUTB2 istheTRG signal Positive logic output L level fi
27. bus DMA forwarding Personal computer of marketing 1 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 Characteristic This board is able to connect 2 cameras with 1 board Also this board is able to input the video signals of the various cameras such as a camera of 2 times speed and a camera of 2 line output types When you use The camera setting program and the various library programs you are able to set up the various conditions to the camera easily mage data can be taken easily to a system memory Q L6 0269 L1 The various cameras of the analogue signal for industry are possible connect Two cameras are possible connect with and be possible a simultaneity catch The cameras of 2 line output type or the progress type or the interlace type is possible connect The video sampling dock is able to select from 5M Hz until 40M Hz This board is able to correspond to internal synchronous camera and external synchronous camera This board is able to forward image data to a system memory by DMA forwarding This board is preventing the forwarding leakage of image data because it is installing it with the buffer memory of the 512K bytes This board can transform the signal of 1 horizontal line until 4096 dots This board is able to input the signals until 4096 lines This board can control a random shutter function of a camera This board is in
28. Catch mode SRO2 30d iTRGM 0 Input video dock 5 VCO CLKSEL 12Hz 20 234MHz CLKDV 0 24H 2 20 245MHz CCKDV 0 Detection dock of SYNC SRO3 40H Shutter control clock STCKS 0 HD 63 55 S OUTBOisthe HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1istheVD signal SR06 07H BIOMD1 1 Output signal Negative logic output SR07 07H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2isthe TRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic SMOD2 1 Camera use Vertical effective width 12Hz SR172400H VUBW 400H 1024 lines 24Hz SR17 200H VUBW 200H 512 lines Repeatedly rate of HD SR18 650H HDSC 650 1616 docks Pulse width of HD 158 clocks Repeatedly rate of VD 12Hz SRIA 414H VDSC 414H 1044 lines 2482 SR1A 20AH VDSC 20AH 522 lines Pulse width of VD SR1B 09H VDPW 9H Shutter time counter SR1C xxH TRGW 2xxH Counter setting value Exposuretime Shutter dock HD 80p S x TRGW value 34 S For example if it is 1mS 1 10005 TRGW 212 then exposure time is about 1S 28n16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 5 1 2 It uses it with a partial scan mode When this mode is used 512 lines are able to be taken with about 22 Hz Vertical effective position SR16 12H VUBP 12H The 18th line Vertical effective width SR17 200H VUBW 200H 512 lines Repeatedl
29. 1 01 OOO 0 OUTOO0 80 8 0 000000000000 00000 OOOUOOU INOO0 000000000000 000000 EJ E Lc OOo Oo OC OC OU 00 ooo ___ 7 oe 05 N EDO foooooo ins7 INB6 ines INB4 INB3 INB2 000000 GTRG A GTRG B VD B HD B V D A HD A A OB OB WEN A WEN B WEN A 000000 000000 V D B HD B M a VD A HD A 0000 OUTB6 74 506 0 0 OUTB7 47 503000 20 OUTBO RS4220 0000000000000 0RS4200000000000000000000 OUTB5 0000000000070000 00000000TrL000000000 00 000000000 INBO 14 5 INB7 67 2 40 5 5V INB6 79 0 30V LO 0 80 o5v 000000 0 8 BIOMDO 70 000000 OUTANBOQ 120000 00000 5 70000000 0 70 0 0 00 0 00 0
30. 2003 Rev 1 01 3 3 2 It uses it with a random mode and external GTRG mode Camera mode CMRMD 0 Oneline output camera 1 unit Input video dock MQCKS 0 TI 1200A 28 636MHz TI 1250A CLKSEL 0 SRO2 00H CLKDV 1 0 TI 1250A 31 028MHz CCKDV 0 Detection dock 5 SRO3 80H Shutter control clock STCKS 0 HD 63 55u S OUTBOistheHD signal BIOMDO 1 Output signal Negative logic output SR05 207H SPOLO 1 Negative logic SR06 83H SMOD1 1 Camera use OUTB1istheVD signal SR07 85H BIOMD1 1 Output signal Negative logic output SPOL1 1 Negative logic H level fixed SMOD1 0 Wide use OUTB2isthe TRG signal BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic SMOD2 1 Camera use INB7 isthe external BIOMD7 0 Input signal signal Negative logic SPOL 7 1 Negative logic IN put SMOD7 1 Camera use Input dock TI 1200A SR10 1C7H VCA 1C7H 62 937x455 28 636MHz SR10 1EDH_ VCA 1EDH 62 937x493 31 028MHz Exposure time sets up it on the side of the camera Because it is HD synchronous the camera sets up it to the V reset mode 20 116 Microtechnica Doc No MTPCI DD V1 01 Date 1 May 2003 Rev 1 01 3 4 TI 150A camera It is 640x 480 659x 494 progress camera of 2 line output and be possible a random shutter Signal that is connected to the board are a video signalx 2 a HD signal a VD signal a TRG signal It is used the external synchronous mode VIDEO1 of
31. Horizontal frequency 31 5K Hz Vertical frequecy 60Hz SROB position of video signal Horizontal effective SR35 280H OUBW 280 640pixels Vertical effective SR36 20H OVBP 20H Repetedyrateot HD BSL SKHZ ______ pPulsewidthofHD Repatedyrateo VD _______ Pusewidthot VD _______ ____ 40 16 Microtechnica 2 2 SVGA monitor Resolution of a screen Scan mode Porarity of SYNC Output video clock Horizontal effective position of video signal Horizontal effective width Vertical effective positi on Vertical effective width Repeatedly rate of HD Pulse width of HD Repeatedly rate of VD Pulse width of VD Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 800x600 video clock 40M Hz Horizontal frequency 37 9K Hz Vertical frequecy 60Hz SRO8 1H OVMD 0 SVGA S 800x600 OTRSM ______ __ 1 Positive logic SR30 420H OCA 420H 37 9k 1056 40M Hz SR34 52H OU BP 52H The 82th dot SR35 320H OU BW 320 800pixels SR36 16H OV BP 16H The 22th lines 600 lines 37 9KHz o GHz 2 2 XGA monitor 1024x768 video clock 65M Hz Resolution of a screen Scan mode Porarity of SYNC Horizontal frequency 47 8K Hz Vertical frequecy 60Hz SRO84 1H OVMD 0 XGA_S 1024x768 OTRSM 1 Positive logic position of video signal width Vertical effective SR36 16H OV BP 16H The 22th lines position Vertical effective widt
32. OUT Port 8 xx08H word Progress counter from GTRG input B SR 25H OUT iN OUT NS byte Port 14 xx14H Pointer clear of the output buffer memory for a monitor 4 6 Power supply and Dimension Rated Voltage Rated Current Outer Dimension V A LxWxH 1 0 OUT IN T OUT OUT OUT UT 59 HOVE 10 175x 106x 16 12V 10 0 05A 4 7 Environment condition of Use Bus specification PCI quasi standard Ambient Temperature DOO c Ambient Humidity RH with no dew condensation Dust Especially to be not many Corrosiveness gas A nonexistent case 9 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 5 PCI bus This board is installing the PCI bus chip PCI 9080 made PL X Only the DMA channel 0 1 function is being used Setting of the internal register of the PCI bus chip becomes needed in the case that the DMA channel is used Table 5 1 Contents of the PCI configuration Object 1 0 word Devicel D Venderl D Valuein this board 4444 4D54 Status Command ClassCode Revision ID BIST H Latency C L Size PCIBARO PCI base address Internal register of memory map 2 word PCIBAR1 PCI base address Internal register of i o map 2 2 2 2 2 fe ee ee ee ee IZ GENE EN I O Lat Min Gnt Int Pin Int Line 1 4D54 MT PCI VenderlID of MicroTechnica 4444 DD PCI DevicelD of this boar
33. SPOL1 1 SMOD1 1 BIOMD2 1 SPOL2 1 Output signal Negative logic SR05 07H Camera use SR06 207H SR07 03H Output signal Negative logic Camera use Output signal Negative logic H level fixed SMOD2 0 Wide use Horizontal effective position SR1424AH UNBP 4AH The 74th dot Horizontal effective width SR15 280H UNBW 280 640 pixels Vertical effective position SR16 0DH VUBP 0DH The 13th line Vertical effective width SR17 FOH VUBW 0H 240 2 480 lines Repeatedly rate of HD SR18 30CH HDSC 30CH_ 24 54M 780 31 468K Hz Pulse width of HD SR19 3EH HDPW 3EH 62 docks Repeatedly rate of VD SR1A 106H VDSC 106H 31 468K 262 120 1Hz Pulse width of VD VDPW 9H One screen data number 4B000H 307200 Channel setting value of DMA 25800H 153600 DMA uses both channel 0 1 EVEN field is forwarded with CH 1 ODD field is forwarded with 0 Order of the field becomes with EVEN ODD EVEN ODD EVEN is thetop side on drawing 30 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 5 2 2 It uses it with a random mode The shutter switch of a camera is setting RDM SROO 11H CMDMD 1 1 Command mode CMRMD 1 Shutter mode SRO1 81H Shutter Hue mie ___ mode al Scan mode ________ Non intelace Catch mode mode SR02 10H Input video dock MQCKS 0 24 5454MHz CLKSEL CLKDV 0 CCKDV 0 Detection dock of SYNC SRO3 40H
34. 2 400 The shutter time is able to control with the width of the trigger pulse if the shutter switch of a camera is set up in 9 36 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 1 3 It uses it with the 240 200 100 98 lines scan mode The mode switch of a camera is set up to NT PT PO The following setting valueis changed Vertical effective position 240 SR16 0CH VUBP 0CH The 12th line 200 SR16 21H VUBP 21H The 33th line 100 98 SR16 21H VUBP 21H The 33th line Vertical effective width 240 SR17 gt 0H VUBW F 240 lines 200 SR17 C8H VUBW C8H 200 lines 100 98 SR17 62H VUBW 62H 98 lines Repeatedly rate of VD 240 SR19 107H VDSC 107H 263 lines 200 SR19 F 2H VDSC F 2H 242 lines 100 98 SR19 8FH VDSC 8FH 143 lines Other setting value are the same as the setting of the normal mode 37 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 A 2 Example of setting to a monitor parameter 1 The setting to the monitor in the VGA mode 1 1 VGA monitor 640x480 25 175MHz SRO8 B0H Horizontal effective SR34 2AH_ OUBP 2AH_ The 42th dot width Vertical effective SR36 20H OVBP 20H The 32th lines position SR38 320H OHSC 320H_ 25 489M 810 31 47KHz OVDW 02H _ 2 lines 1 2 SVGA monitor 800x600 40M H z Scan mode Horizontal effective SR34 52H OU BP 52H The 82th dot position of video signal Horizont
35. 8H sR 08 OVMD jormmsM T Pot 212 11 D10 09 De D7 D0 Ee ae SR5 SRO SR 10 input video clock is set up to catch the image VCO SR 14 UNBP The horizontal effective position of an input signal is set up 9 bits data D8 DO SR 15 UNBW Horizontal effective width of an input signal is set up 12 bits data D11 D4 0000 SR 16 VUBP Vertical effective position of an input signal is set up 8 bits data 07 00 SR 17 VUBWT The vertical effective width of an input signal is set up 12 bits data D11 DO SR 18 A horizontal repetition rateis set up 12 bits data D11 DO SR 19 HDPW The pulse width in a horizontal synchronous period is set up 8 bits data 07 VDSCI A vertical repetition 15 set up 12 bits data 011 00 1 VDPWI The pulse width in a vertical synchronous period is set up 5 bits data D4 DO 1 TRGWQ The width of trigger pulseis set up 10 bits data 09 0 Port SR _ DI2 DI1j DI0 D9 08 D DD SR 30 OCAQ The output video clock for the display is set up 11 bits data D10 DO ET SR 35 OUBW The horizontal effective width of the output signal is set up 11 bits data 8H 8H SR 3A OVSC A vertical repetition rate of output signal is set up 11 bits data SR 3B OVDWI The pulse width in a vertical synchronous signal is set up 4 bits data
36. EJ EJ EJ C3 EJ E3 E3 EJ EJ EJ EJ EJ E3 EJ E3 EJ EJ EJ E3 C3 C3 O L3 L3 E3 E3 EJ EJ E3 EJ EJ E3 EJ EJ EJ E3 EJ EJ E3 EJ EJ EJ EJ EJ E3 EJ E3 EJ EJ EJ F3 C3 C3 O noo oOo noo oOo 1 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Data I A List of the 0800000000 B Example of setting 70000 B 1 Example of the setting to a camera O Video signal of the EIA standard E 00000000 O00 Camera of SONY 65000000060 O00 Cameraof NEC 0000000600 000 CameraofJAl O00000000 000 Camera of TEL 0000000000 000 Camera of the Takenaka system 0000000000 B 2 Example of the setting to monitor 0000000000 monitor VGA D LI LI 00 000 Setting of superimpose 0000000000 Example of the setting to forwarding DMA 1 FL H1 D 000 Image catch by forwarding 00000000 DMA 000 Forwarding to the buffer memory for the monitor by forwarding 0 DMA DDIU 2 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 D uuu 00000 DBugpnPcecinpngunuuupnuunnuunnunnanugpnuupnpna dgnaud 000000000000
37. Opinion D 6 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 4 About the inquiry of the technology contents O00 000000000000 This product regarding technical furthermore you request an inquiry with E mail or fax Please fax it to the sales department address with the following model Oooo Question of the technology contents 000000 MICROTECHNICA Ltd LH LEE BL EE UE BE BED DH Service department of Sales department FAX 00 0000 0000 http www mi crotechni ca co j p 000 Assignment oe Name uo ___ dwm o Address NN TRECE Telephone Facsimile Jmm The question T 0 0 7 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 5 About the repair request 800000060 In the case that you ask the repair of this product you enter the malfunction contents symptoms in the following model and please send to repair department with the product It breaks out well that the malfunction contents do not reproduce by use environment Please let me know the point in the case that you are able to borrow use environment T E B E D C HH D EL E D E 00000000
38. a video signal of the camera is connected to A and VIDEO2 i s connected to B The scanning switch of the camera sets up it to 21 mo de You set ON to the termination of a synchronous signal The video clock 12 2727M Hz the horizontal frequency 15 734kHz the vertical frequency 60H z At the time of 2 line output 3 4 1 It uses it with a normal mode Camera mode SROO 11H CMDMD 1 Two line output camera 1 unit 1 Cid SRO1 00H SRO2 14H Input video clock MQCKS 0 12 2727MHz CLKSEL CLKDV 1 CCKDV 0 Detection clock of SYNC SR03 80H Shutter control dock OUTBOisthe HD signal BIOMDO 1L Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1istheVD signal SR06 07H BIOMD1 1 Output signal Negative logic output SR07 203H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 istheTRG signal Negative logic output H level fixed BIOMD2 1 Output signal SPOL2 1 Negative logic SMOD2 0 Wide use SR19 3EH SRIA 106H VDSC 106H One screen data number 24B 000H 307200 Channel setting value of DMA 25800H 153600 DMA uses both channel 0 1 EVEN field is forwarded with CH 1 ODD field is forwarded with 0 Order of the field becomes with EVEN ODD EVEN ODD EVEN is thetop side on drawing 21 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 3 4 2 It us
39. ability of the PCI buses of 32 bits 33MHz are biggest 133MHz S The actual speed is below this forwarding speed 14 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 4 Moderegister The SR cord the SR register of port 8 is set up in port C A SR cord is set up with 6 bits of DO D5 Port C is byte access The mode and counter are set up with port 8 The access is only the output As for the access of port 8 the byte and word are possible The upper byteis disregarded in the case that it gained access to the setting of the byte register with the word The list of the command is shown below the SR cord 0 to 9 SR 00 SR 00 07 __ 06 D5 D3 pD2 b 1 0 sR amp SRs SR3 __ 582 SRI SRO GTSMD CMDMD CMR RNDST sis STRMDl M cckpv1 STCKSl cse Ed Bromoa spora D3 SR3 C SR 03 EHCKS1 EHCKSO _____ sasi BIOMD4 SPOL4 8 sr 08 ovmp J Pn CH 8H 8H SR 02 ITRSM ITRGM MQCKS CLKSEL 1 8H 8H 8H H 8H 8H 8H 8H 8H 8H 8H 8H 6 4 1 Setting of the camera SR 0 SR 00 One line output camera 1j Two line output cameras The camera of 1 line output is able to be connected to 2 units As for 2 cameras there is the same necessity One camera of 2 line output is able to be connected 1
40. interval between VD and VD the adjustment in exposure time becomes possible It is to adjust the value of the setting value of VDS C Other setting value are the same as the setting of the normal mode Exposure time Shutter dock HD 63 55u S x VDSC 34 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 Camera of the Takenaka system 6 1 TM 6700AN camera It is 640 480 648x 484 progress camera and be possible a random shutter Signal that is connected to the board are a video signal a HD signal a VD signal a TRG signal It is used the external synchronous mode A video signal of the camera is connected to A HD signal 9 pin TRG signal 6 pin The scanning switch of the camera sets up it to 21 mode The termination of a synchronous signal sets up it to ON The video dock 24 49M Hz the horizontal frequency 31 468kHz the vertical frequency 60 2 6 1 1 It uses it with a normal mode The mode switch of a camera is setting NRM NO SROO 00H CMDMD 0 Oneline output camera 1 unit CMRMD 0 External trigger mode GTSMD J Shutter mode RNDST 0 Synchronous mode SRO1 00H SYCMD 0 External sync HD VD Input clock MQCKS 0 VCO KDV Shutter trigger mode STRMD ___ __ __ ITRSM O SR02 0H ITRGM 0 CLKSEL 0 25 489MHz CLKDV 0 Detection dock of SYNC SRO3 40H_ EHCKS 1 Shutter control clock STCKS 0 Pr OUTBOisthe HD signal B
41. picture only As for the output from this board the RGB same image data is output 5 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 4 Specification of hardware 4 1 Input video signal This board is able toinput 2 channels of the monochrome video signal Explanation Number of Two input channels Two cameras of 1 line output are able to Input be connected or one camera of 2 line output is able to be connected Input signal The monochrome 1Vpp 75Q terminatted Video positive Composite video signal Synchronous negative or 0 7V pp Only a video signal synchronous frequency Range 1KHz 60K Hz Vertical synchronous Setting with the program frequency Range 1Hz 100Hz method 2 1 interlace connector DSU B 15P connector synchronous VD output signal Internal HD input signal Setting with the program synchronous VD input signal Composite video signal Trigger control lc UT Setting with the program 6 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 4 2 Output video signal It is the output video signal for a monitor It is able to connect to a monitor of multi scan correspondence tems Explanation Output signal R G B video signal 0 7Vpp 750 terminated synchronous frequency Vertical synchronous Setting with the program connector Three lines connector of
42. termination of a synchronous signal The video dock 29 5MHz the horizontal frequency 31 25kHz the vertical frequency 100Hz 11 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 3 1 It uses it with a normal mode Trigger switch of the camera be sang to N Twoline TT camera 1 SROO 11H unit RNDST 0 Normal scan SR01 00H SY CMD 0 External sync HD VD STRMD 0 ITRSM 0 Non intelace ITRGM 0 Field Camera mode Command mode External trigger mode Shutter mode Synchronous mode Shutter trigger mode Scan mode Catch mode SRO2 20H Input video clock Ens Detection dock of SYNC of SYNC Shutter control control clock OUTBOistheHD signal Negative logic output OUTB1istheVD signal Negative logic output OUTB2 istheTRG signal Positive logic output L level fixed MQCKS 1 CLKSEL 0 CLKDV 0 eee 0 E BIOMDO 1 SPOLO 1 SMOD1 1 BIOMD1 1 SPOL1 1 SMOD1 1 BIOMD2 1 SPOL2 0 SMOD2 0 SR05 07H SR06 03H SR07 03H VCO 29 5MHz Output signal Negative logic Camera use Output signal Negative logic Camera use Output signal Positive logic Wide use Repeatedly rate of HD SR18 3B0H HDSC 3BOH 944 docks 29 5M 2 944 31 25 Hz Pulse width of HD SR19 66H HDPW 66H 102 docks Repeatedly rate of VD SR1A 139H VDSC 139H 313 lines 31 25KH H 8Hz Pulse width of VD SR1B 09H VDPW 9H l9Olines One screen data number 6BAO0H 440832 Channel setti
43. 0 00000 00000 000 0000000 0000000 041 00000000 Input signal for camera Frame memory Generation of theClock and setting to a minute frequency MTPCI DD Board 12 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 000 100000 00 i 0 ecH i X n n n 0 00000 0 i dod iN ___ 000 D 000 0000000 Rated Voltage Rated Current Outer Dimension V A LxWxH 0000 fio __ xx00H IN i E L3 c3 c CJ OO L3 Ojo L3 IN IN IN Oo Oo bey 0 0 0 Ojo Oyo Ojo CJ oO Ei m 12V 10 0 05A 00000 13 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 00 00000 PCINO O00 0 1 1 9080
44. 00 00000 00 0000 200 4 100 20KHz 00 50 10K Hz STCKS100 00000 00000 00000 0000000 5 6 7 ooo sR 07 06 105 jo fom foo L BIOMD7 0 000 100 SPOL7 0 oo 000 1000 SMOD7 0 onn HIT 0 23 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 5 8 te sr 8 SR 08 OVMD VGA_S VGA 00000 TOU 0D0000000000000000000 0D00000000000000000000000000000000000000 000000000 OITRSM 000000 2010000000000000 00 TRSM0000 10000 OITRSMO 00010 0 00 0 00 O O 0000000 512K000 200000 oO 1 2 OOO 100000000 EI Ea ES ed ES EE E EST
45. 0000000000 10 aub IP 00000000 06 75 0000 52 0000000000000 000000 INBeppBDaud addiNB7ZInOdDAB 00000 00000 00000 INB6 GTRG B 0 1 6 000 00000 000 B 00000000 H00 COOO0 INB156 00000 D VD D 000000 0 0 15 15 15 860 WEN BD D D D D D D D 29 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 000 000000000 0000 0 160 0 00000 0000 80 1600 00000 0000016000000000 A0 GTRC B0000000000000000 000000000000000 FFFFH0000O0 C00C0000000000000 000 0 0 15 734K Hz HD 6355u SO 0 0 PCIOO 0CO0O00000000000000000000000000000000 0002000000000 000 000000000 DMA 0000 0 0 0 PCI 90800 0000000000000 A0000 00 0 0 0 Duognnaudg spnnupnnu upnbMAngpnaupninunpnanpnaagpa DMAD 0 0000 512K0 000 256 1611000000 0000 0
46. 0000000000000000000000 000 219 0000 0000 8H SR 36 0D000000000000000000 00 0 080 T 0000000000000000 sR37 ovuwgp000000000000000000000000 0 ben 000 tm 0000000000000000 H0000000000000000 0000 sR 38 oHsco00000000000000000000000000 000 0 0 210 2000 bin 16000 48008 000000000000 8H sR 39 OHDWOOOOO0000 HD000000000000000m Dm 00000000 iad D0000000000000000000000000000000000 0000000000000000 P Ret e anoo nononoononooon 00000000 0100 00000 00000000000000 Edd RE 0000000000000000 0000 49 0900MHzj PLLWVCOOQUOU00U00000U000000U000 26 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 1 1 XD D Y MAX D U 640 480 1638 800 600 1310 1024 768 1024 1152 864 910 1280 818 819
47. 0000H of the ODD data 01825800H Data number of each field 25800H System memory address of the Parameter 02000000H with bytesx4 addresses 45 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Setting value 1 2 3 5 start 02000000H 02000004H 02000008H Transfer byte counter 0200000CH Function register 02000010H PCI address register 02000014H Local address register 02000018H Transfer byte counter PCI address register Local address register 0200001CH Function register 02000020H PCI address register 02000024H Local address register 02000028H Transfer byte counter 0200002CH Function register 02000030H PCI address register 02000034H Local address register 02000038H Transfer byte counter Preparation You set the parameter to the system memory 02000000H before the DMA 0200003CH Function register 00000002H Chain completion 01800000H Anywhere good 00000008H F orwarding start 00000002H 02000011H 01800000H 00000000H EVEN field data 00025800H 02000021H 01825800H 00000004H ODD field data 00025800H 02000031H 02000000H 00000008H F orwardi ng completion 00000002H It makes the DMA channel enable 0001H It sets up it to the chain mode 0000 0 41 forwarding address A Setting of the byte number of 0000 0000H S ee 98H Setting of the head address of the 0000 0000H system memory of forwarding source OH 46 116 Microtechnica
48. 2 937KHzx VCA cek The resource clock of the board is 49 0909MHz Theinput clock is generated from this resource dock The input clock is able to be set up in the range of 5M 40M Hz in the case of an external synchronous mode Also the PLL VCO circuit for input clock generation is available The dock frequency is able to be transformed with the setting of the VCA counter In the case that necessary frequency is not the minute circumference of 49MHz VCO is selected It sets up it with MQCKS 0 CLKSEL 1 in the case that the input clock is same the frequency that is done the minute circumference from 49MHz 24 545MHz half of 49MHz are selected Clock that was selected becomes the minute circumference of a resource clock and stability becomes best CLKSEL 0 VCO 1 Half of Resource clock Input clock In the case that the frequency is not the minute circumference of 49MHz VCO is selected Setting up it with CLKSEL 0 in the case that a camera is used with external synchronous mode VCO is selected In the case that a camera is not able to use with external synchronous mode setting up it in MQCKS 1 CLKSEL 1 and 1 2 of VCO selected CLKDVI 0 0 1 1 1 1 2 2 1 3 3 1 4 It does the input clock a minute circumference furthermore CCKDVI1 0 0 1 1 1 1 2 2 1 4 3 1 8 camera dock Clo for the preparation of the HD signal 17 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 4 4 Settingofthe
49. 5 3 2 It uses it with a random mode Camera mode SROO 11H CMDMD 1 Two line output camera 1 unit o Synchronous mode SYCMD 0 External sync HD VD Shutter trigger mode STRMD 1 TRG mode TRSM Catch mode SRo2 14H Input dock 12 2727MHz Detection dock of SYNC Shutter control clock SR03 82H STCKS 252K Hz 3 97u High speed SR03 80H STCKS H D 63 55u Middle speed SR03 81H 0 16 670 Low speed OUTBOisthe HD signal BIOMDO 1 Output signal SR05 07H SPOLO 1 Negative logic SR06 83H SMOD1 1 Camera use SRO7 87H BIOMD1 1 Output signal Negative logic output SPOL1 1 Negative logic SMOD1 1 Camera use BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic SMOD2 1 Camera use INB7 isthe external BIOMD7 0 Input signal signal Negative logic SPOL 7 1 Negative logic IN put SMOD7 1 Camera use The 74th dot 640 pixels The 12th line 480 lines 12 2727M 780 15 734K Hz 62 clocks VDSC 20DH 15 734K 525 30Hz 9 lines SR1C xxH Counter setting value Exposuretime Shutter dock x TRGW value 8 S For example if it is 1mS 1 1000S shutter clock2H D TRGW 16 then exposure ti me is 1 025mS If it is shutter clock 252kHz TRGW 250 then exposure time is 3 97x 250 8 1 001mS If it is shutter clock VD it is possible long time setting but it becomes to biggest 250mS 5 3 3 It uses it with a Restart Reset R R mode By expanding the
50. At E E ED 2 Monochrome sequential image capture board 00000000 Operation Manual 0000000 MICROTECHNICA Co Ltd 1 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Declaration The products MTPCI DD 2 Monochrome sequential image capture board to which this dedaration relates are in conformity with the following standards or other normative documents 55022 1998 A1 2000 Class A Information technology equipment Radio disturbance characteristics Limits and methods of measurement EN 55024 1998 Al 2000 Information technology equipment Immunity characteristics Limits and methods of measurement following the provisions of EMC directive 89 336 EEC as amended by 92 31 EEC and 93 68 EEC Subject products are manufactured tested according to appropriate quality control procedures Warning This product is able to use simultaneous 4 boards In usage of the condition this product is matching EMC and also FCC standard In the case that you use the BNC connector you wind to 1 time the BNC cable toa ferrite core and please use Wear wristband etc in the case that you contact this product when the product is acting and please pay attention so that static electricity is not transmitted to this product The external triggerd signals is not connected to the standard camera cable Please use the exclusive use cable the case that you wa
51. GETC to camera A B output with GETC of port 0 When CMDMD is set up in 1 the GETC command of port 0 is output to both A B in the casethat a camera is 2 line output Condition setting of a camera camera It is in the case that you want only one side of a camera as GETC The GETC command is output separately A B 6 7 7 Camera A or 6 camera B 1 7 both camera 0 The imagedata is taken each time the INB 6 7 signal is input if the GETC command is output in the case that INB6 INB7 isused as the GTRG signal 1 It becomes the catch signal of A B camera with only the signal of INB7 15 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 4 2 Setting of the shutter control SR SR 01 RNDST Mode setting of SYCMD1 0 acamera Synchronous mode STRMD2 1 0 Normal scan triggering every VD of a shutter sequence 1 Random scan At the time of image catch you trigger it with program O external HV L external H 2 iinternal C 3 iinternal HV 00 A camera is synchronized by using HD VD synchronous signal of the board 1 A camera is synchronized by using the HD signal of the board A VD signal extracts from the video signal of the camera and use it A board is operated with the video signal of a camera HD VD signal is extracted from the video signal of the camera and use it 30 A board is operated with HD VD signal of a
52. H STCKS 2 252KHz 3 97u high speed SRO3 80H STCKS 0 sp middle speed SR03 81H STCKS 1 HDO 63 55 SO low speed VD 16 67mS OUTBO is the HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1is the VD signal SR06 83H BIOMD1 1 Output signal Negative logic output SRO7 87H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 is the TRG signal BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic SMOD2 1 Camera use OUTB7 is the GTRG signal BIOMD7 0 Input signal Negative logic IN put SPOL7 1 Negative logic The shutter control by SMOD7 1 Camera use external signal input is possible DONPISHA Shutter time counter SR1C XXH TRGW XXH Counter setting value Exposure time Shutter dock TRGW value 8 S For example if it is 1mS 1 1000S and makes a shutter dock the HD and 16 are set up TRGW then exposure time become 1 025mS 1 976S If it makes shutter dock 252kHz and 250 are set up TRGW then exposure ti me become 3 97 250 8 1 001mS If it makes a shutter dock the VD it is possible long time setting but it becomes to biggest 250mS 9 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 2 2 It uses it with the restart reset R R mode By expanding the interval of VD and the next VD the adjustment in exposure time becomes possible It adjusts it with the setting value of the VD repeat rate counter VDSC Other sett
53. IOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use SR06 207H BIOMD1 1 Output signal Negative logic output SRO7 03H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 isthe TRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic H level fixed SMOD2 0 Wide use VCA 195H UNBP 5CH UNEW 280 VUBP 21H VUBW I1EOH HDSC 32AH HDPW 52H VDSC 20DH VDPW 9H 35 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 1 2 It uses it with a randoml mode The mode switch of a camera is setting ASY the shutter switch is selected from 1 to 8 Camera mode SROO 00H CMDMD 0 Oneline output camera 1 unit Command made External trigger mode ae E Shutter mode Synchronous mode SRO1 91H Shutter trigger mode Scan made Catch made rTRGM O __ ____________ Input dock MQCKS 0 25 489M Hz CLKSEL 0 CLKDV 0 CCKDV 0 Detection dock of SYNC SRO3 40H Shutter control clock STCKS 0 HD 63 55 S OUTBOistheHD signal BIOMDO 1 Output signal Negative logic output SR05 07H SPOLO 1 Negative logic SR06 07H SMOD1 1 Camera use OUTB1listheVD signal SRO7 05H BIOMD1 1 Output signal Negative logic output SPOL1 1 Negative logic H level fixed SMOD1 0 Wide use OUTB2 istheTRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic SMOD2 1 Camera use Exposure time Shutter clock HD 31 8u S x TRGW
54. M1C camera It is the 1300x 1026 camera of 1 300 000 pixels for industry Signal that is connected to the board are a video signal a HD signal a VD signal a TRG signal It is used the external synchronous mode The video dock 20 234M Hz In the case of random trigger mode the only HD signal is used for external synchronization It uses it with a normal mode SRO0 00H CMDMD 0 One line output camera 1 unit CMRMD 0 STRMD O Non intelace MQCKS 0 CLKSEL 0 CLKDV 1 CCKDV 0 SRO3 80H EHCKS 2 3MHz stcks 0 4 1 1 Command mode External trigger mode Shutter mode Synchronous mode Shutter trigger mode Scan mode Catch mode Input video clock SRO1 10H SR02 04H Detection dock of SYNC Shutter control clock OUTBO is the HD signal Negative logic output OUTBIisthe VD signal Negative logic output H level fixed OUTB2 is the TRG signal Negativelogic output BIOMDO 1 SPOLO 1 SMOD1 1 BIOMD1 1 SPOL1 1 SMOD1 0 BIOMD2 1 SPOL2 1 SMOD2 0 SR05 07H SR06 07H SR07 01H Output signal Negative logic Camera use Output signal Negative logic Wide use Output signal Negative logic Wide use 23 116 Microtechnica 4 1 2 SROO 00H External trigger mode Synchronous mode Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 It uses it with a random mode and external trigger mode CMDMD 0 Oneline
55. May 2003 Rev 1 01 HBEBCEHEEEE DE OE DE BEES HR10 12P DMC BC A DMC BC B DMC BC D E d2V DMC BC C HR10 12P 7 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 000 0000000 03 3 VGAQGOO00000 DSUB 15P 00000000000 uma 0000 0000 0 BOOOU 0 7 7500 0000000000000 0 ooo000 Tooo aonuuugnnuuu TTLOOO 000000000000 E 00000000000 000000000000
56. O signal name Pin Usage signal name I ___ Common for the camera ID amv The DC 12V power supply for the camera T D Common for the camera __ _ Input of the video signal CH A input 2 signal CH A in out Input output signal of TTL CH A in out Input output signal of TTL signal CH B input Input output signal of TTL signal CH A input Input output signal of TTL Jasno Common for thecamera 00 __ ____ Input of the video signal CH B input 2 signal CH B in out Input output signal of TTL VD B m CH B in out Input output signal of TTL CH A output Input output signal of TTL Shutter trigger signal CH B output Input output signal of TTL The d c 12V power supply for the camera is using the d c 12V power supply of a personal computer Please pay attention to the consumption current It does not connect the load of 0 5A over 2 A videosignal VIN is connected to the BNC touching plug and also DSUB 15P inside the board A video signal is terminated with a 750 4 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 3 2 Connection with the monitor This board is ableto display the data of the buffer memory in the multiple scan monitor for a general personal computer Table 3 2 T
57. OM E V1 01 Date 1 May 2003 Rev 1 01 4 2 2 It uses it with a random mode and external trigger mode SROO 11H CMDMD 1 Two line output camera 1 ET 34 Commandmode si mode 1 RMD 1 Catch mode SROZ 14H_ ITRGM 0 Input video clock MQCKS 0 12 2727MHz CLKSEL CLKDV 1 CCKDV 0 Detection dock of SYNC SRO3 80H Shutter control clock STCKS 0 HD 63 55u S OUTBOistheHD signal BIOMDO 1 Output signal Negative logic output SR05 07H SPOLO 1 Negative logic SR06 C7H SMOD1 1 Camera use OUTB1istheVD signal SRO7 C5H BIOMD1 1 Output signal Negative logic output SPOL1 1 Negative logic H level fixed SMOD1 0 Wide use OUTB2 istheTRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic SMOD2 1 Camera use INB6isthe WEN signal BIOMD7 0 Input signal Negative logic input SPOL 7 1 Negative logic SMOD7 1 Camera use INB7 is the external BIOMD7 0 Input signal signal Negative logic SPOL 7 1 Negative logic IN put SMOD7 1 Camera use Shutter time counter Shutter mode of the camera sets up it to the single trigger mode 26 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 5 Camera of TELI 5 1 CS3910 camera It is a camera of 1 300 000 pixels for industry Signal that is connected to the board are a video a HD signal a VD signal a TRG signal TRG 11 pin It is used the external synchronous mode The
58. V1 01 Date 1 May 2003 Rev 1 01 4 2 CV M10 BX RS camera It is 640x 480 659x 494 progress camera of 2 line output and be possible a random shutter Signal that is connected to the board are a video signalx 2 a HD signal a VD signal a TRG signal External synchronization is not abletouseit in the random shutter mode VI DEOI1 of a video signal of the camera is connected to and VIDEO2 isconnected to B The scanning switch of the camera sets up it to non interlace SW5 ON mode The video dock 12 2727M Hz the horizontal frequency 15 734kHz the vertical frequency 60Hz At the time of 2 line output 4 2 1 It uses it with a normal mode SROO 11H CMDMD 1 Two line output camera 1 Command mode si CMRMD 1 SRO1 00H Shutter Hu tage mode STRMD 0 _ OE lt Scanmde _________ Non intelace Cath mode SR02 14H Input video dock MQCKS 0 12 2727MHz CLKSEL CLKDV 1 CCKDV 0 Detection dock of SYNC SR03 80H Shut cant dodade OUTBOisthe HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1istheVD signal 5606 07 BIOMD1 1 Output signal Negative logic output SR07 203H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 isthe TRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic H level fixed SMOD2 0 Wide use 25 116 Microtechnica Doc No MTPCI DD
59. _____ 00000 DMAT 00 000 0 6 10 00 0000000000000000 DMADD 0000000000000000 0 0 0 GMODT D C1 C C LL D 1 1 1 1 111 11111 1 1 0 DU uuu D uuu 0 00 0 00 000000 000000 0000000 ur 17 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 000 000000000 0000000 OO OO OO Oo EJ E E3 E E E Oo Oo EE OO Oo OO OO Oo Oo Oo Oo Oo EJ E E3 E EE E E OO Oo OO Oo Oo oo L3 LB Lj E 07 o 105 0 D2 o OH IT 000000 000000000 00 E DMAG 1 0 500 100 Sn n nd d 9080 DMAER 1 0 0
60. a Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 Data forwarding to the output buffer memory by DMA In the case that the data of a system memory is sent to the output buffer memory with DMA forwarding DMA channel 1 is used The value designated in the local address is selected from the following 3 The upper class address makes 0 0 Non interlace EVEN field of Interlace 4 ODD field of Interlace 8 Clear of the input pointer of the output buffer memory 2 1 In the case of Non interlace data Address of the system memory of forwarding source 01800000H Forwarding byte number 0004B000H Contents Setting value Clear of the input pointer of the output buffer memory Forwarding start t makes the DMA channel enable Setting of the DMA mode Setting of the head address of the system memory of forwarding source Setting of the local address of the forwarding address Setting of the byte number of forwarding data Setting of the pointer 0000 0000H DMA is started 0003H Clear of the input pointer of the output buffer memory Forwarding completion Order Address OUT port14H 0001H 0000 0841 0180 0000H 0000 0000H 0004 BOOOH 2 10 In the case of interlace data In the casethat it is divided into 2 field the DMA forwarding for each field becomes necessary You set the OI TRSM bit in 1 If a chain mode is used the series of forwarding is possible System memory address of the EVEN data 0180
61. a shrink type VD input signal 4 3 Sampling frequency of the image data 000 In the case of external synchronization The range 5 40MHz Thesetting step about 63kHz 000 In the case of internal synchronization The video clock 24 5454M Hz 12 2727MHZ 8 18MHz 6 14MHz 000 A D converter 8 bits high speed flash types Transformation frequency 40M Hz MAX in monochrome use 7 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 4 4 Frame memory This board is installing the FIFO buffer memory of the 1M byte for the image data output Also the FIFO buffer memory of the 512K bytes for the DMA forwarding is being installed Fig 4 1 The flow of image data Input signals for camera i enm EE H i 0000 PCI bus VGA Monitor _ Synthesis Generation of theClock and E seti ngto a minute frequency Board 8 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 4 5 1 0 This board is using the io address of 6 ports Those ports is necessary to catching the image data and to setting of parameter etc Address of the port is allocated in the unit of 4 bytes Fuga DIE LUE RR No Porto xx0OH OUT bye Commandregste D Porto IN byte StMusreise 0 SCS longword The line counter for DMA forwarding A SR 0 Port 8 Xx08H word Progress counter from GTRG input A SR 24H
62. al effective OUBW 3209 800pixels width Vertical effective SR36 16H OV BP 16H The 22th lines position Vertical effective width SR37 258H OVBW 258H Repeatedly rateof VD__ SRIA 276H OVSC 276H 38 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 13 In the casethat the image data of XC HR300 camera is output SVGA monitor The data of 768 74 287 2 is displayed SRO8 C1H SVGA 768 574 287 gt 2 position of video signal position 1 4 XGA monitor 1024x768 65MHz SRO8 80H Horizontal effective SR34 8AH OU BP 8AH The 138th dot position of video signal Horizontal effective 1024pixels width Vertical effective SR36 16H OV BP 16H The 22th lines position 39 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 Thesetting to the monitor in the VGA S mode The HD VD signal that becomes a standard is output from the personal computer Vertical frequency Refresh rate makes 6030 5 Hz the standard It is not able to use it with this mode in the case that it is not able to set up the refresh rate to about 60 Hz It is able to display it to XGA monitor 1024x768 Even the same display mode there is a delicate difference in frequency and display position etc by a graphic board Thefollowing setting is a major value It becomes necessary to adjust the value in accordance with a personal computer 2 1 VGA monitor 640x480 video clock 25 175MHz
63. ame that are described to this manual are trade mark or trademark of each company 000000000000 pDugmnuinunupupgugpupdudopungdagiguuulluu Attention on use Please use it in the appropriate environment where this product was designated with this manual As for the use in other environment there is the fear of a wrong action Solder face etc of this product the hand please do not touch directly There are the fear of an injury and malfunction In the casethat you incorporate this product to a personal computer or this product be connected to a camera please do after you turn off the power supply Please usethe cable that matches fit the camera in the case that this product and camera are connected Thereis the fear that damages the camera and this produc in the case that the cable with different pin arrangement is used 0000000 00
64. amera It is the shutter trigger signal to a camera To synchronize this trigger signal to the HD signal thetrigger input is delayed 1 or 2HD Thetrigger signal requires the pulse width of 2HD over In the case that the GTSMD bit is set in 1 INB6 does not use Takein of camera A and B are produced with only the INB7 signal In this case INB6is able to use it as WEN A signal input A WEN signal is able to use as the substitution of a VD signal input in the case of external H sync mode or internal Csync mode In this mode the INB1 5 become the WE N signal if the INB1 5 is setted in a camera signal 25n16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 8 Externaltrigger counter Input port The external trigger signal is input and the progress time is counted from It is the port that inputs this progress time Pot DI6 D8 D7 D0 SR 24 Counter A 16 bit counters SR 25 Counter B 16 bit counters It isthe progress counter from the time that the external trigger signal input Counter A is done 0 dear with the input of the GTRG A signal and counter B is done 0 dear with GTRG B signal input The counter is done increment constantly and stop with FFFFH It does not circulate The clock of the counter is 15 734K Hz 63 55 S 6 9 DMA forwarding to the system memory Input port The image data is forwarded to a system memory by DMA forwarding through the PCI bus DMA forwar
65. back edge of a vertical synchronous signal 8H SR 37 The vertical effective width of the output signal is set up 10 bits data D90 DO Thedock of the counter is the horizontal synchronous signal HD The width is the line number that wants to display it 8H SR 38 OHSQ A horizontal repetition rate of output signal is set up 11 bits data 010 DO The clock of the counter is the output video clock The horizontal scan rate is set up as the 16 clocks unit and the subordinate position 4 bits are disregarded and become 0 8H SR 39 The pulse width in a horizontal synchronous signal is set up 8 bits data D7 DO The clock of the counter is the output video dock The width of the horizontal synchronous signal is set as the 2 docks unit and the most significant bit is O 8H SR 3A 5 A vertical repetition rate of output signal is set up 11 bits data D10 O 00 Theclock of the counter is thehorizontal synchronous signal HD It is set up as the 1 line unit 8H SR 3B OVDW The pulse width in a vertical synchronous signal is set up 4 bits data D30 DO The clock of the counter is the horizontal synchronous signal HD 21 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 The output dock is generated in resource dock 49 0909M Hz and PLL VCO circuit The memory of the 1M bytes is installed as the output buffer memory for a monitor display The scan
66. becomes a pair Y ou set up the unused signal to input 2 The that was set up as for the camera is used as the following signal HD A Horizontal synchronization camera A 10 VD A Vertical synchronous camera A 20 STRG A Shutter torigger output camera A 30 STRG B Shutter trigger output camera B 4 HD B Horizontal synchronization camera B 50 VD B Vertical synchronous camera B 60 GTRG B Extenal tigger input camera B 70 GTRG A Extenal tigger input camera A 24 116 Microtechnica HD A camera A Horizontal synchronization HD B camera B Horizontal synchronization VD A camera A Vertical synchronous VD B camera B Vertical synchronous STRG A camera A Shutter trigger output signal STRG B camera B Shutter trigger output signal GTRG A camera A External trigger input signal GTRG B camera B External trigger input signal Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 It makes the HD signal with 2 counters HDSC HDPW The unit of the counter clock is a camera dock If INB 0 4 is set up to the input signal for a camera and in the case of the internal synchronous mode INBO 4 becomes the HD signal input of a camera It makes the VD signal with 2 counters VDSC VDPW The counter clock is an above HD signal In the case of the external synchronous H mode internal C mode or HV mode if INB 1 5 is set up to input signal for a camera the INB1 5 become VD or WEN input signal of a c
67. camera TheINB 0 1 signal of the connector is used as HD VD signal 2 TRG VD 4 TRG TRG It is the mode that does not do a shutter control Even in the casethat the shutter control is carried out on the side of the camera it is this mode 1 A shutter is controlled with only the STRG signal It uses it for the camera that shutter time is decided with the pulse width of the STRG signal Or it uses it for the camera that a STRG signal is used as thetrigger signal only STRG signal of the pulse width that the TRGW counter set up is produced The STRG signal ends and after 3 or 4HD the VD signal is produced and the image catch is started 21 A shutter is controlled between the STRG signal and VDsignal It uses it for the camera that shutter time is decided between the STRG signal and VD signal STRG signal is occurred and VD signal is produce after the pulse width that the TRGW counter set up STRG signal width becomes 1 clock of a TRGW counter clock Shutter is controlled between a VD signal STRG signal It uses it for the camera that shutter time is decided between the VD signal and STRG signal VD signal is occurred and the STRG signal is produce after the pulse width that the TRGW counter set up STRG signal width becomes 1 clock of a TRGW counter clock 4 A shutter is controlled between 2 STRG signals It uses it for the camera that shutter time is decided between 2 STRG signals STRG sig
68. d 2 This address isthe base address toaccess a internal register of the PCI 9080 In the case of memory mapping access PCIBARO is used In the case of i o mapping access PCIBAR1 is used In the case of i o ports of this board PCIBAR2 is used The least significant bit of the base address is making 0 00H 04H 08H OCH 10H 14H 18H PCIBAR2 PCI base address OH 4H 8H CH 30H 34H 38H 10 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 In the case that a DMA channel is used setting of the PCI 9080 internal register is necessary The following only register is set up and do not set up the other register i o DMACh1 PCI Address 11 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 Interface with a program 6 1 Input output port This board is using the io address of 6 ports The base address sets up it with PCIBAR2 Itis allocated in i o space of 16 bits and monopolize 32 bytes Porto IN Byte Statusregiste A Theline counter DMA forwarding SR 0 peg eee SR 24H Port 8 xx08H Word Progress counter from GTRG input B Portc __ IN ____ Longword_ The line counter for _ Commandregister B Pot10 IN Byte j Statusregste B Port 14 Xx14H OUT Byte Pointer dear of the output buffer memo
69. de 0000 1941H memory of forwarding address forwarding source data 90 A4H Setting of the pointer 0000 0008 8 DMA is started 0003H OUT port0 10H You output the GETC command with the counter 11 A8 A9H You check the completion of DMA D4 bit 1 icona output the command Outputting the last command because image input may not be ending even if DMA forwarding ends you complete and force it Please pay attention because forwarding may act wrong when the next GETC command is output in condition without imag input being ended 1 20 In the case that it forwards it with the chain mode When a DMA mode 15 set up to the chain mode you are able to take image data in the continuation The memory address where next DMA parameter is housed to the function register is set up Example The data of a plural screen is taken in a continuation in the system memory Those data are done in the same memory address as a screen unit top writing The memory area and also parameter area of 1 s amp reen are secured to 43 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 the system memory The parameter is 4 words of a PCI address Local addresses Forwarding byte number Function register Address of the system memory of forwarding address 01800000H Forwarding byte number 0004B 000H Memory address where houses the parameter 1234000H Order Address Setting value Preparation You set the pa
70. dinate position 4 bit of the counter is 0 When GETC was ayutput the counter is done 0 clear 6 10 Forwarding from the system memory to buffer memory for the monitor 1 O port 14H is only the output port and be disregarded the data n the case that you do data forwarding to the buffer memory for a monitor by DMA forwarding this command is used This command makes 0 pointer of the buffer memory Pot D7 D6 05 p4 03 92 DO Clear the pointer of the output buffer memory for a monitor Data be disregard In the casethat the data of the system memory is sent to the output buffer memory by DMA forwarding DMA channel 1 is used Thesetting value of a DMA LOCAL address is able to select it from 3 kinds The upper address makes 0 0 non interlace or interlace and the 1st field EVEN 4 theinterlace and the 2nd field ODD 8 the dear of the input pointer of the output buffer memor y In the case that the data of the non interlace type is forwarded you designate 0 In the casethat the EVEN field data of an interlace type is forwarded you designate O In the casethat ODD field data is forwarded you designate 4 In the casethat it clears the pointer you designate 8 Sothat the pointer becomes the head of a buffer memory before forwarding you implement OUT 14H The data is disregarded You implement OUT 14H to complete forwarding after forwarding 27 116 Microtechnica HOUUUUUO
71. ding is relying on the PCI 9080 chip The data from camera A is forwarded the data from channel 0 camera B by using DMA channel 1 Before forwarding DMA the data is housed to the buffer memory F IF O of the 512K 256K x 16695 The data that was input with the GET C command is housed once to this buffer memory The DMA forwarding is carried out to the data that was input to this buffer memory The DMA forwarding is carried out in the unit of 32 bits 4 bytes One data in here indicates 4 picture elements of the image data 8 bits 1 byte 31 24 23 16 15 87 0 43 data N42 data N 1 data Correspondence with the system memory address is the following data 0 070 DObits data 1 0150 D8bits data 2 0230 D16bits data 3 D31 D24bits 26 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 DMA forwarding is controlling it to 1024 words 2048 byte a unit DAM forwarding be irrespective of the scanning line of a camera and is managing it with forwarding data number 1 DMA forwarding byte counter input port DMA forwarding number of the input data from camera A reads it with the counter value of port 8 SR 0 DMA forwarding number of the input data from camera B reads it with the counter value of port C DEINEN D31 D16 015 00 32 bit counters The data forwarding for camera A use channel 0 mac 32 bit counters The data forwarding for camera B use DMA channel 1 The subor
72. dock 2 584 EHCKS1 0 Clock for HD VD detection STCKS1 0 0 12 1 6M 2 3M NRM 3 1 5M VD signal and field signal need to be extracted from the video signal of a camera in the casethat a synchronous 15 1 2 High speed camera etc Horizontal synchronous frequency is the range of 400 60KHz the frequency is a rough standard 1 Two times speed camera etc Horizontal synchronous frequency is the range of 20 40 Hz Even the pulse width etc of a synchronous signal influences 24 camera Horizontal synchronous frequency is the range of 100 20K Hz 30 Low speed camera etc Horizontal synchronous frequency is the range of 5 10K Hz 0 HD 1 VD 2 45 S 252KHz 3 The clock of shutter control is selected The dock that uses it for the TRGW counter is selected It makes the shutter sequence in the circuit of the board and TRG signal VD signal that were designated are produced automatically and the i mage data is taken 18 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 4 5 SettingofthelO signal SR 5 6 7 The input output polarity usage of thelO signal that useit with port 4 are set up Pot SR D7 fbe D5 p4 _ 03 02 bi foo 6 4 6 Setting of the monitor SR 8 D7 D6 D5 D4 D3 D2 D PPP SR 08 0 It is a personal computer picture synthesis It superimposes the Setting output ima
73. e HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1istheVD signal SRO6 07H BIOMD1 1 Output signal Negative logic output SR07 203H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 istheTRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic H level fixed SMOD2 0 Wide use 17 116 Microtechnica 3 2 2 E mode External trigger mode tri OS mode SR00 200H Shutter mde si mode Synchronous mode SR01 91H Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 It uses it with a random mode CMRMD 0 Oneline output camera 1 unit ITRSM O ITRGM MQCKS 0 24 5454M Hz CLKSEL CLKDV 0 CCKDV 0 STCKS 0 HD 63 551 S BIOMDO 1 Output signal SPOLO 1 Negative logic SMOD1 1 Camera use BIOMD1 1 SPOL1 1 SMOD1 0 BIOMD2 1 SPOL2 0 SMOD2 1 BIOMD7 0 Catch mode mode Input dock Shutter mode SRO2 10H a Scan mode Detection Detection clock of SYNC of SYNC SR03240H OUTBOisthe HD signal Negative logic output SR05 207H SR06 83H OUTB1istheVD signal SRO7 85H Negative logic output H level fixed OUTB2 isthe TRG signal Positive logic output Output signal Negative logic Wide use Output signal Positive logic Camera use INB7 is the external GTRG signal Negative logic SPOL 7 1 Negative logic IN put SMOD7 1 Camera use Because it is HD s
74. e SYCMD 0 External sync HD VD Shutter trigger mode STRMD 0 t ITRSM 0 Catch mode SRO2 14H ITRGM 0 Input video clock MQCKS 0 12 2727 2 CLKSEL 1 CLKDV 1 CCKDV 0 Detection dock of SYNC SRO3 80H EHCKS 2 3MHz normal Shutter control dock 5 OUTBO is the HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1is the VD signal SRO6 03H BIOMD1 1 Output signal Negative logic output SRO7 03H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 is the TRG signal BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic L level fixed SMOD2 0 Wide use Horizontal effective position Horizontal effective width Vertical effective position Vertical effective width Repeatedly rate of HD Pulse width of HD SR19 3EH HDPW 3EH Repeatedly rate of VD SRIA 20DH VDSC 20DH Pulse width of VD SR1B 09H VDPW 9H When you output the GETC command 80H after above setting it is input 1 screen 8 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 2 2 It uses it with the E DONPISHA mode SRO00 200H camera 1 unit GTSMD 0 o o y Shutter mode RNDST 1 Random shutter Synchronous mode SRO1 81H SYCMD 0 External sync HD VD Shutter trigger mode STRMD 1 TRG mode ITRSM 0 Catch mode SRO2 14H ITRGM 0 Input video clock 12 2727MHz Detection dock of SYNC EHCKS 2 3M Hz normal Shutter control clock SR03 82
75. es it with a normal mode SR00 00H camera 1 unit GrsMD 0 SRO1 00H STRMD 0 O iTRGM 0 Input dock MQCKS 0 12 2727MHz CLKSEL CLKDV 1 CCKDV 0 Detection dock of SYNC SRO3 80H sio OUTBOisthe HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1istheVD signal SRO6 07H BIOMD1 1 Output signal Negative logic output SR07 03H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 isthe TRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic H level fixed SMOD2 0 Wide use When you output the GETC command 80H after above setting it is input 1 screen 15 116 Microtechnica 3 1 2 ET mode External E mode SROO 00H Shutter mode mode Synchronous mode SR01 91H Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 It uses it with arandom mode and external GTRG mode CMRMD 0 One line output camera 1 unit ITRSM O ITRGM 0 MQCKS 0 12 2727 2 CLKSEL CLKDV CCKDV 0 STCKS 0 HD 63 551 S BIOMDO 1 Output signal SPOLO 1 Negative logic SMOD1 1 Camera use BIOMD1 1 SPOL1 1 SMOD1 0 BIOMD2 1 SPOL2 0 SMOD2 1 BIOMD7 0 Catch mode sid mode Input dock Shutter ESO RN mode SR02 14H a Scan mode sid Detection Detection dock of SYNC of SYNC SR03 280H Shutter control dock OUTBOA isthe HD signal Nega
76. es it with a random mode The camera is setting to V reset mode SW201 9 Camera mode SROO 11H CMDMD 1 Two line output camera lunit 1 000 ______ GrsMD 0 SRO1 91H Input video dock MQCKS 0 12 2727MHz CLKSEL 1 CLKDV 1 CCKDV 0 Detection dock of SYNC SRO3 80H EHCKS 2 Shutter control clock STCKS 0 HD 63 551 S OUTBO is the HD signal BIOMDO 1 Negative logic output OUTB1is the VD signal Negative logic output H level fixed OUTB2 is the TRG signal Positive logic output INB7 is the external GTRG signal Negativelogic IN put Horizontal effective position Horizontal effective width Vertical effective position Vertical effective width Repeatedly rate of HD Pulse width of HD Repeatedly rate of VD Pulse width of VD Shutter time counter SRO5 07H SR06 83H SRO7 85H SPOLO 1 SMOD1 1 BIOMD1 1 SPOL1 1 SMOD1 0 BIOMD2 1 SPOL2 0 SMOD2 1 BIOMD7 0 SPOL7 1 SMOD7 1 Output signal Negative logic Camera use Output signal Negative logic Wide use Output signal Positive logic Camera use Input signal Negative logic Camera use SR19 3EH HDPW 3EH 62 clocks SR1A 106H VDSC 106H 15 734K 262 60H 2 SR18 30CH HDSC 30CH 12 27M 780 15 734KHz SRIB 09H VDPW 9H SR1C 01H TRGW 01H Counter setting value 1 Exposuretime sets up it on the side of camera 22 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 4 Camera of J Al 41 CV
77. f HD SR19 66H HDPW 66H 102 clocks Repeatedly rate of VD SR1A 139H VDSC 139H 313 lines 31 25K 2 313 99 8 2 Pulse width of VD SR1B 09H VDPW 9H Shutter time counter SR1C XXH TRGW XXH Counter setting value Exposure time Shutter dock x TRGW value For example if it is 1mS 1 1000S shutter clock HD TRGW 31 then exposure time is 0 992mS If it is shutter clock 252kHz TRGW 252 then exposure time is 3 97 252 1mS If it is shutter clock VD it is possible long time setting but it becomes to biggest 250mS 13 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 3 2 It uses it with a high rate mode High rate switch of the camera be setting to 20 and trigger switch is setting to RR or MI You can catch the 244 lines data 200 times a second or the 88 lines data 400 times a second Camera mode CMRMD 1 Two line output camera 1 SROO 11H unit CMDMD 1 A B A o o GISMD _ ___ RNDST O SROl 00H SYCMD 6 STRMD 9 ITRSM 0 SR02 20H ITRGM O Input video clock MQCKS 1 VCO CLKSEL 0 29 5MHz CLKDV 0 CCKDV 0 peon dok YNC eto EHCKS 2 SRO3 40H_ STCKS 0 S BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use SR06 83H BIOMD1 1 Output signal Negative logic output SR07 87H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 isthe TRG signal BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic L level f
78. f RGB the same image data is output Pot D12 01 010 09 08 ___07 00 ______ 8H SR 30 OCA The output video clock for the display is set 11 bits data 0100 DO The subordinate position 2 bits is disregarded and become 0 A calculation formula is shown below VGA Output dock frequency 62 937KHz x Setting value of the counter S Output clock frequency H D frequency of a personal computer x Thesetting value of the counter The restriction of the output frequency of the VCO circuit is 1OM 75M Hz At the time of a VGA mode please set value of the counter with 160 1190 8H SR 34 OUBPT The horizontal effective position of the output signal is set up 10 bits data D9 DO The clock of the counter is the output video clock The position is it which clock number passed from a back edge of a horizontal synchronous signal It is the setting of 2 clock units The least significant bit is disregarded and become 0 8H SR 35 The horizontal effective width of the output signal is set up 11 bits data D100 DO The least significant bit is 0 The dock of the counter is the output video dock Width becomes the pixel number that wants to display it 8H SR 36 The vertical effective position of the output signal is set up 9 bits data D80 DO The clock of the counter is the horizontal synchronous signal HD The position is the position which passed only the line number from the
79. ge of a personal computer and camera image ofa 1 Itisthe display output from a board Without superimposing it monitor displays the only camera image OITRSM 0 Non interl ace 1 2 1 interlace In the casethat the 2 1 interlace camera is used if the ITRSM bit is scanning 7 the OITRSM bit is set in 1 mode The buffer memory is divided in the 512K byte 2 block The input data of each field is housed in a different memory block Image output is non interlace mode The data output is output alternately each block 0 It is treated as the 1M byte 1 block In the case of 2 line output camera the input is non interlace but it synthesizes 2 line output to put 1 line and it must display it Therefore the OITRSM bit is set in 1 HVPOL Polarity of It is the setting of the logic of a synchronous signal a HD VD synchronous signal are a negative logic signal generally synchrono But at the time of SVGA usethe ordinariness is used with positive us signal logic Therefore please set HVPOL in 1in the case that it uses it with SVGA If itis a VGA mode the synchronous signal is output with positive logic Ifitisa VGA S mode the synchronous signal that was input is considered as positive logic 19 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 5 Setting of the counter for the camera signal SR 10 1C Pot 1 J DI2 DI1 D10 D9 08 D7 DO ____ 1 R 10 It sets up it t
80. ger mode STRMD 2 TRG VD mode ITRSM 0 Catch mode SRO2 14H _ ITRGM 0 Input video clock MQCKS 0 12 2727MHz CLKSEL 1 CLKDV 1 CCKDV 0 Detection dock of SYNC SRO3 80H EHCKS 2 3M Hz normal Shutter control clock STCKS 0 OUTBO is the HD signal BIOM DO 1 Output signal Negative logic output SR05 07H SPOLO 1 Negative logic SRO6 03H SMOD1 1 Camera use OUTB1is the VD signal SRO7 07H BIOMD1 1 Output signal Negative logic output SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 is the TRG signal BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic SMOD2 1 Camera use Horizontal effective position The 78th dot Horizontal effective width 640 pixels Vertical effective position The 12th line Vertical effective width 240 lines Repeatedly rate of HD 780 clocks Pulse width of HD 62 clocks Repeatedly rate of VD 263 lines Pulse width of VD 9 lines Shutter time counter SR1C XXH TRGW XXH Counter setting value Exposure time 63 55 S x TRGW value 10 42 S 6 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 High speed shutter mode TT mode CMRMD 0 One line output SROO 00H l unit Command mode mode DMD 0 External mode GTSMD 0 Shutter mde mode RNDST 1 Random shutter Synchronous mode SRO01 83H SYCMD 0 External sync HD VD Shutter Shutter trigger made mode SRO2 14H Input video clock MQCKS 0 12 2727MH
81. h SR37 300H OV BW 300H 768 lines mewanauo Reewedyreg Vo SH PusewidhotVD 41 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 A 3 Example of the setting to DMA forwarding DMA channel of the local register of PCI 9080 Address Usage Contents Setting value Hexadecimal PCI Address Head address of the system XXXX XXXX ae source Transfer Byte Count Byte number of forwarding data 90H ____ Descriptor Pointer 0000 0008 oa Mode DMACh1 Mode 0000 1941 memory of forwarding address source Transfer Byte Count Byte number of forwarding data A4H Descriptor Pointer 0000 0008 Reise i Command status Register 01 03 800 90 A8H set DMA channel 0 94 A4 set up DMA channel 1 Although the regiser of 1 9080 15 32 bit units the access of the byte unit word unit are possible 80H 84H 88H 8CH 90H 94H 98H 9CH AOH A4H 42 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 1 DMA forwarding to the system memory 11 In the case that 640x480 of image data are forwarded I mage data number 4B000H 307200 bytes Head address of the system memory of forwarding address 01800000H Byte number of forwarding data 00048000 640x 480 307 Kbyte Setting value A8 A9H It makes the DMA channel enable 0001H 80 94H Setting of the DMA mo
82. he assignment of the pin number of the connector for the VGA monitor DSU B 15P j ROUT R Video output The maximum value of video signal level is d 0 7V Itis terminated with a 750 G OUT G Video output The maximum value of video signal level is EE ERN 0 7V Itis terminated with a 750 B OUT Video output The maximum value of video signal level is EE LS EN 0 7V Itis terminated with a 750 R Video input The maximum value of video signal level is 0 7V Itis terminated with 50 ry in the case of superimposition GIN G Video input The maximum value of video signal level is 0 7V 1 15 terminated with a 750 ME aul in the case of superimposition B Video input The maximum value of video signal level is 0 7V It is terminated with a 750 uui lll in the case of superimposition U GND enp enp J commn aa a signal input VD IN Vertical synchronous TTL the case of superimposition Lud pd signal output signal output np ___ ______ The output signal of the above table is the signal VGA output There is VGA output of only this board also there is the superimposition VGA output of this personal computer output and of the board output n the case of superimposition mode the input signal of the above table connects personal computer VGA output This board is abletoinput and output a monochrome
83. ing DDMD Remainder data is forwarded forcibly in the unit of each screen Theinput data is not guaranteed when the next screen input Setting of the begins before this DMA forwarding ends however Please usethis forwarding mode only when there is a sufficient margin in the share of the mode PCI bus Compulsory DMA forwarding time ends with about 100p S Setting of the In the case of GMOD 0 and 1 screen input the DMA forwarding is processing of carried out irrespective of a DDMD bit remainder 0 Remainder data does to as it is This remainder data is forwarded data by the DMA with the next screen input Only the remainder data of the final screen causes to forward it forcibly by the DMA I mage catch monitor and the contents change by top writing The actual catch is instructions to carried out from the next vertical synchronous signal the output Data does not be taken to the output buffer memory It continuously catch the image data Until this bit is set up in 0 it is catching the deta and forwarding to the output buffer memory Setting of catch In the case of a continuation catch data is done top writing because mode to the memory capacity is 1 frame the output 0 It is the catch mode of only 1 screen buffer memory GMSL Data of camera B is taken to the output buffer mage selection 0 Data of camera A is taken to the output buffer command 13 116 Microtechnica GETMC Data of the camera is taken to the output buffe
84. ing make the setting of when that is normal SROO 00H camera 1 unit External trigger mode GTSMD 0 1 Normal Synchronous mode SRO1 00H SYCMD 0 External sync pm emt iow Smp Non intelace ITRSM O Nonintelace Catch mode SR02 14H ITRGM 0 EVEN field Input video clock MQCKS 0 12 2727MHz CLKSEL 1 CLKDV 1 CCKDV 0 Detection dock of SYNC EHCKS 2 3M Hz normal Shutter control clack SRO3 80H sTCKS _ ss OUTBO is the HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SRO5 07H SMOD1 1 Camera use OUTB1is the VD signal SR06 83H BIOMD1 1 Output signal Negative logic output SRO7 87H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 is the TRG signal BIOMD2 1 Output signal Positive logic output 5 2 0 Positivelogic L level fix SMOD2 0 Wide use Exposure time Shutter dock x VDSC value If it is VDSC 525 65535 the exposure time is 33mS 45 cMOMD 10 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 3 XC HR300 camera It is 768x 574 782x 582 progress camera of 2 line output method and be possible a random shutter Signal that is connected to the board are a video signalx 2 a HD signal a VD signal a TRG signal It is used the external synchronous mode VIDEO1 of a video signal of the camera is connected to A and VIDEO2 is connected to B The scanning switch of the camera sets up it to 21 2 1 interlace mode You set ON to the
85. ix SMOD2 0 Wide use Input clock SR10 1D5H 62 937kHz 46929 517MHz Horizontal effective position SR14 9CH UNBP 9CH The 156th dot Horizontal effective width SR15 300H UNBW 300H 768 pixels Vertical effective position SR16 19H VUBP 19H The 25th line Vertical effective width 244 lines SR17 7AH_ VUBW 7AH 244 lines 12222244 50 lines 25 2 50 SR17 19H VUBM 19H dis Repeatedly rate of HD SR18 3BOH 944 docks 29 5M Hz 944 31 25KHz Pulse width of HD SR 19 66H HDPW 66H 102 clocks Repeatedly rate of VD 156 lines 78 lines SRIA 9CH VDSC 9CH 156 3125k 156 200Hz SRIAMEH VDSC4EH 78 3125k 78 400Hz 84 lines SR1A 54H VDSC 54H__ 84 372 field Sec ines SRIA 3BH VDSC 3BH_ 59 530 field Sec Pulse width of VD SR1B 09H VDPW 9H When you output the GETC command 80H after above setting it is input 1 screen 14 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 3 Camera of NEC 3 1 TI 400A camera It is 640x 480 progress camera and be possible a random shutter Signal that is connected to the board are a video signal a HD signal a VD signal a TRG signal It is used the external synchronous mode The video clock 12 2727M Hz the horizontal frequency 15 734kHz the vertical frequency 30Hz 30 frame In the case of random trigger mode the only HD signal is used for external synchronization 3 1 1 It us
86. mera Camera 23 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 1 Explanation of the input output signal OUTB6 The signal is output with open collector output by the 74L S06 OUTB7 It is pulled up to the 5V and pulled up tothe resistance of 4 7K O External load is 50 30V and be possible the drive of about 20mA OUTBO Signal is RS422 driver output The RS422 driver is differential output but OUTB5 each signal use one side output only It is possible thedrive of TTL level load In this case you use the signal with sink current within 30mA INBO The signal is TTL input Input IC is LV14 of 3 3V system but the INB7 signal of the 5V system is possible connect INB 6 7 is possible to 30V input with it that the protection circuit is added The input level is H 2 4 5 5V INB 6 7 only 30V L 0 80 0 5V input output of BIOMDOJ 7 Setting of Input output polarity the logic of OUT INBO 7 is polarity set up with 8 bits of SPOLO 7 LW O00 Hi The logic on the side of the CPU and on theside of 11 Negative logic the connector agree in the case of positive logic Setting of For those signals whether for the wide use or an usage camera use are set up with 8 bits of SMODO 7 Theabovesetting is applied even in the case of the signal for the camera use Theoutput driver of DO D2 and D3 D4 bit are a pair in relation to RS422 Accordingly the setting of the input output
87. n D OH mma cerc DDMD GETMC GMMD GMSL 10 008 cerc DDMD 16 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 GETC 0000000 ooo oooooo pMag 000000 000 0000000 00000 0650000600 0000000 000 100 5000 00 0000 00 0 0 D DM D D D D 000 D 0 0 0 0 0 0 0 0 00000000000000000008 ______ 0 0 0 0 0 0 0 0 0 GMMD 1 0 ________ 000 8000000000000000000000 GETMC lili i 0 0 0 0 0 0 00000000000000 0 000000000 0 000 ADDDODDDODODODODODODOD
88. nal is occurred and the 2nd STRG signal is produce after the pulse width that the TRGW counter set up STRG signal width becomes 1 clock df a TRGW counter clock The 2nd STRG signal ends and after 3 or 4HD the VD signal is produced and the image catch is started 16 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 4 3 Setingofthedock 1 58 5 0 Non interlace 1 2 1 interlace When it is non interlace mode it becomes image catch of a field unit The catch of the image data is started from the next VD signal in the non interlace mode The catch of the image data is started from the next VD signal in the case of theinterlace camera H owever it becomes uncertain from which field it started the catch the case of the interlace camera the data that was forwarded DMA is divided in the front the second half of the memory Determination of the field is possible with theF LDG status bit If FLDG bit is 1 data of the 1st field is sent in the memory first half and the data of the 2nd field is sent in the memory second half If FLDG bit is Oit is reverse O The catch of the image data is started from the 1st field in the interlace mode The catch of theimage data is waited maximally 33mS in a usual camera Data of the 1st field EVEN is sent in the memory first half and the data of the 2nd field ODD is sent in the memory second half MQCKS 0 49 0000MHz 1 6
89. ng value of DMA 235D00H 220416 DMA uses both channel 0 1 EVEN field is forwarded with CH 1 ODD field is forwarded with 0 Order of the field becomes with EVEN ODD EVEN ODD EVEN is thetop side on drawing 12 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 3 2 It uses it with a random mode Trigger switch of the camera be setting to M1 and shutter switch is setting to all OFF Camera mode CMRMD 1 Two line output camera 1 SROO 11H unit J _ mem swa S693 Eare SRO1 81H SRO2 20H Input video clock VCO 29 5MHz Detection clock of SYNC EHCKS 3 1 5MHz Shutter control clock SRO3 C2H STCKS 2 252KHz 3 97 0 high speed SRO3 2COH STCKS 0 HDO 32 SO middle speed SR03 C1H STCKS 1 VDO 10mS low speed OUTBO is the HD signal BIOM D0 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1is the VD signal SRO06 83H BIOMD1 1 Output signal Negative logic output SR07 87H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 is the TRG signal BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic SMOD2 1 Camera use INB7 is the external GTRG BIOMD7 0 Input signal signal Negativelogic input SPOL7 1 Negative logic The shutter control by SMOD7 1 Camera use external signal input is possible Repeatedly rate of HD SR18 3BOH HDSC 3BO0H 944 clocks 29 5MHz 944 31 25KHz Pulse width o
90. nt to use the external triggerd signals irrespective of the above standard Cable is wound to 1 time to the ferrite core 0000000 0 0000000 1 000 EN550220 1998 1 2000 Class A 0000000000000 000 EN55024 19980 1 2000 0000000 893 36 00 0 d 092 30 0 93 68 2 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Copyright Notice 2003 Microtechnica Co Ltd rights reserved Without the written permission of Microtechnica Microtechnica prohibits to copy any portion of this manual It sometimes changes without notice the specifications of this product and also the contents of this manual Microtechnica assumes no responsibility to the influence that happens by the use of this product Company name product n
91. o generate the video clock 10 bits data D9 Doing the VCO output dock a minute circumference it makes the comparative signal of the PLL circuit A PLL circuit controls the VCO circuit so that a standard signal and comparative signal become the same phase The frequency of VCO output is able to calculate it with the next formula Clock frequency 62 937 2 x Setting value of the counter Please set up the valuein 160 to 1023 ranges The horizontal effective position of an input signal is set up 9bits data D8 DO Horizontal clock uses the camera dock The value of a horizontal effective position is set up with the clock dot number from the back edge of the HD signal UNBWJ Horizontal effective width of an input signal is set up 12 bits data Width is set up with the dock dot number from the horizontal effective position Horizontal width is the setting of 16 clock units The subordinate position 4 bits are disregarded and become 0 D11 DO NN VUBPT Vertical effective position of an input signal is set up 8 bits data D7 DO Thevertical counter clock is HD A vertical effective position sets up the line number from the back edge of the VD signal Bl VUBW The vertical effective width of an input signal is set up 12 bits data 0111 DO Width becomes the line number from the vertical effective position of the VD signal HDSQG A horizontal repetition rateis set up 12 bits data 0110 DO The clock
92. o signal 4 2 Output video signal 4 3 Sampling frequency of the image data 4 4 Framememory 4 5 O access EL EZ ESTE L3 L3 r3 L3 L3 r3 L3 L3 r3 rrr Lr 4 6 Power supply and Dimension 14 4 7 Environment Condition of Use 14 PCI bus 15 Interface with a program 61 I O port 17 6 2 Command registration 6 3 Status registration 6 4 Moderegistration 6 4 1 Setting of the camera 6 4 2 Setting of the shutter control 6 4 3 Setting of the dock 1 6 4 4 Setting of the dock 2 6 4 5 Setting of the IO signal 6 4 6 Setting of the monitor 6 5 Setting of the counter for the camera signal 6 6 Setting of the counter for the monitor display 6 7 Selection of wide uselO and camera signal 6 8 External trigger 6 9 forwarding to the system memory 6 10 Forwarding from the system memory to buffer memory for the monitor 0000 33 E OOO E3 E3 E3 E3 EJ E3 E3 E3 E3 E3 EJ Ez E T EST ESE EZ pl EST 7 E73 ET LT ESI E T ET ES E EH E23 ETE ET E NJ UJ 10 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Data volume A List of the command B Example of setting B 1 Example of the setting to a camera Video signal of the EIA standard Camera of SONY Camera of NEC Camera of
93. of the counter is a camera clock In the casethat the scanning mode of a camera is the interlace mode the NN rate is set up to half In this case output becomes to put 1 piece p SR 19 The pulse width in a horizontal synchronous period is set up 8 bits data D7 DO Clock of the counter isa camera dock oe es Tae The clock of the counter is an above HD signal The pulse width in a vertical synchronous period is set up 5 bits data D4 DO The clock of the counter is an above HD signal in TRGW The width of trigger pulseis set up 10 bits data D9 DO The circuit of the board produces the TRG signal VD signal in accordance with appointment automatically and do the catch of image data The shutter time is set up with the counter Theresource clock of the board is 49 0909M Hz The standard signal of the PLL circuit is 62 937K Hz 49 0909MH 2 780 20 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 6 Setting of the counter for the monitor display SR 30 3B The image data that is housed to the output buffer memory for monitor is abletodisplay it in the multiple scan monitor for a general personal computer The output signal is the signal for VGA output When it superimposes personal computer the input signal of the board connects the VGA output signal of a personal computer Because this board is monochrome specification as for the output o
94. otal clock dot number become the following It is a reference value It relys on the specification of the VGA board that use it actually 1 VGA 640x 480 31 5KHz 800 docks OCA 800 2 SVGA 800x 600 37 9KHz 105 docks OCA 1056 3 XGA 1024x 768 47 8KHz 1360docks OCA 1360 The attention Horizontal and vertical effective width needs to be accord with the type number of the image data that are written to the output buffer memory 22 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 7 Selection of wide uselO and camera signal This input output port is port 4 and be accessed with the byte unit It isabletouseit as the signal of the camera signal or the wide use The usage is set up with the command of port 8 to each bit The usage of the signal is decided in the case of camera use In the case of wide use OUTB INB signal are ableto useit for input or for output by setting Wide use output It is controlled with 8 bits of the output port 8 Thesignal is done a latch Wide use input It is able to check signal condition with 8 bits of the input port 8 Pot __ 07 D5 jD4 102 _ 01 bo 8 bit input data Camera GTRG A GTRG B HD B HD A Camera A WEN A Camera Camera Camera B Camera B B Camera A A pot por oe os a jos 5 or bo Sa EA V D B HD B STRG B STRG A VD A d Camera B Camera Camera Camera Ca
95. output camera 1 unit CMRMD 0 GTSMD 0 SY CM D 1 External sync HD B __ RNDST 1 SRO1 91H Shutter trigger mode Scan mode __ Scan mode SR02 04H Input video clock Detection clock of SYNC SRO3 80H Shutter control clock OUTBOistheHD signal Negative logic output SR05 207H SR06 2C7H OUTB1istheVD signal SR072C5H Negative logic output H level fixed OUTB2 istheTRG signal Negative logic output INB6isthe WEN signal Negative logic input INB7 is the external GTRG signal Negative logic IN put Input clock Horizontal effective position Horizontal effective width Vertical effective position Vertical effective width Repeatedly rate of HD Pulse width of HD Repeatedly rate of VD Pulse width of VD Shutter time counter SR19 CH SR1A 414H 5218 09 SR1C 01H MQCKS 0 VCO CLKSEL 0 40 47MHz CLKDV 1 CCKDV 0 57 5 BIOM D0 1 SPOLO 1 SMOD1 1 BIOMD1 1 SPOL1 1 SMOD1 0 BIOMD2 1 SPOL2 1 SMOD2 1 BIOMD7 0 SPOL 7 1 SMOD7 1 BIOMD7 0 SPOL7 1 SMOD7 1 VCA 283H UNBP D8H UNBW 500 VUBP 02H VUBW 400H HDSC 650H HDPW CH VDSC 414H VDPW 9H TRGW 01H Output signal Negative logic Camera use Output signal Negative logic Wide use Output signal Negative logic Camera use Input signal Negative logic Camera use Input signal Negative logic Camera use Shutter mode of the camera sets up it to the single trigger mode 24 116 Microtechnica Doc No MTPCI DD OM E
96. pulse width of a trigger signal if the switch of a camera is set up to the pulse control mode 5 3 CS8530 camera It is 640x 480 659x 494 progress camera of 2 line output and be possible a random shutter Signal that is connected to the board are a video signalx 2 a HD signal a VD signal a TRG signal It is used the external synchronous mode VIDEO1 of a video signal of the camera is connected to A and VIDEO2 is connected to B The video clock 12 2727M Hz the horizontal frequency 15 734kHz the vertical frequency 2 32 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 5 3 1 It uses it with a normal mode SROO 11H CMDMD 1 Two line output camera 1 NB Command mode si mode CMRMD 1 samoa 0 Catch mode SRO22M4H ITRGM O ESSEN Input video dock MQCKS 0 12 2727MHz CLKSEL CLKDV 1 CCKDV 0 Detection dock of SYNC SRO3 80H_ EHCKS 2 Shutter control clock STCKS 0 7 OUTBOisthe HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1istheVD signal SR06 07H BIOMD1 1 Output signal Negative logic output SRO7 03H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 istheTRG signal BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic L level fixed SMOD2 0 Wide use 33 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01
97. r memory for a Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 3 Status register Y ou input the status register with port 0 port 10 It istheregister that monitors the condition where takes an image Only the byte access is Port 10 becomes for camera B and port 0 for camera A Pot D7 D6 b5 04 03 02 01 OH CameaA GETG GETS GETMG NSVD FLDG DMAG DMAER 10H Camera 8 GETG cers GETMG NSVD FLDG DMAG DMAER GETG t becomes 1 with the output of the GETC command It becomes 0 with the completion of image catch GETS 1 0 It becomes 1 after the next vertical synchronous signal after the GET C command was output It becomes 0 with the completion of image catch GETMG It is 1 while the image data inputs it to the output buffer memory for a monitor t becomes 1 with the output of the GETM C command It becomes with the completion of image catch NSVD It becomes 1 at the time of period throughout of a vertical synchronous es It becomes 0 other than the period of a vertical synchronous signal took it first is an ODD field it becomes 1 becomes 0 DMAG 1 0 It is 1 during DMA forwarding After forwarding ends it is delayed 50 OMS Th ANS Sversneow ses DMAER 1 0 In the case that the forwarding mistake resulted it becomes 1 It is held until the next GETC command is output in the case that it became 1 The data forwarding
98. rameter to the system memory 01234000H before the DMA start 01234000H PCI address register 01800000H 01234004H Local address register 00000000H 01234008H Transfer byte counter 0004B 000H 0123400CH Function register 01234009H 0001H 0000 1B41H memory d forwarding address Setting of the local address of the forwarding 0000 0000H source 0000 0000H The memory address where next DMA 0123 4009H parameter is housed is set up The upper 28 bit becomes the memory address where houses the next parameter in the case of the chain mode although the subordinate 4 bit of the function registration is a function bit Setting of 16 byte units DMA is started 0003H You output the GETC command COH command If it makes the D1 bit of the function 0123 400BH registration 1 chain mode ends and even DMA forwarding ends A8H Y ou check the completion of DMA forwarding D4 bit 1 Completion OUT port After completion was detected you output the is output command DMA forwarding is repeated in accordance with the parameter of the system memory in the chain mode The PCI address and Forwarding byte number can also be changed Even that sets up a plural parameter and connect them is possible If the value of a function register is changed to 01234019H from 0123400CH in the above the next parameter address becomes 01234010H gt I m 44 16 Microtechnic
99. ry for a monitor 1 A byte port it is able to access with the word In the case that it uses it as output the upper byteis disregarded In the case that it uses it as input the upper byte becomes uncertain 12 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 6 2 Command register The command register sets up it with port 0 port 10 The command control the catching method of image data Only the byte access is Port 10 becomes for camera B and port 0 for camera A It do even the take in of camera B only with a command of port 0 in the case that the CMDMD bit is 1 Pot ___ 07 be 05 D3 02 fpr 00 0H GMOD GETMC GMMD GMSL 10H Camea8 GETC oomo GETC 1 Theimage catch from video signal is started This bit becomes 1 with the next vertical synchronous signal DMA I mage catch forwarding is finished automatically when the byte number that instructions was set up is input GMOD Plural screen of the imagedata is taken DMA forwarding byte number corresponding to the screen number that takes it is set up Setting ofa catch Takein data number relys on the byte that forwards it by DMA A mode forwarding byte number is set up with the data number of the screen unit the case that the data number does not agree the input data is not guaranteed must agree with the byte number of DMA forward
100. stalling the frame memory the output buffer memory of the 1M bytes for a monitor display Data of a frame memory can be output with the video signal of a VGA quasi standard 2 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 3 Constitution of the Board 3 1 Connection with the camera As for the method of the connection with the camera there are the following 2 method Onecaseis the connection by a DSUB 15P pin connector With this connection for a camera an external synchronous control becomes possi ble Another case is the connection by BNC connector With this connection this board uses the synchronization of the NTSC composite video signal Canera connecti o Wde use BNC connect or deo input connect or deo i nput 2 VGA out put Video 1 Common for the camera Signal Input of the video signal 0 0 Videoinput 2 BNC B Common for the camera Input of the video signal B Signal 3 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Table 3 1 The assignment of the pin number of the connector for the camera DSUB 15P Signal for the camera and signal name of a wide use Camera Wide use DI D
101. tive logic output Camera A SR05 07H SR06 83H SRO7 85H OUTB1 5 isthe VD signal Negative logic output Output signal Negative logic Camera B Wide use SR05 38H SR06 8 0H SRO7 91H H level fixed OUTB2 3 isthe TRG signal Positive logic output Output signal Positive logic Camera use INB7 is the external GTRG signal Negative logic SPOL 7 1 Negative logic IN put SMOD7 1 Camera use Because it is HD synchronous the camera sets up it to the V reset mode When you output the GETC GMOD command after above setting it is input a screen every an external signal Input signal 16 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 3 2 TI 480A camera It is 640x 480 progress camera of the 2 times speed and be possible a random shutter It is possible to catch 1 frame with 16mS Signal that is connected to the board are a video signal a HD signal a VD signal a TRG signal It is used the external synchronous mode The video dock 24 5454M Hz the horizontal frequency 31 5kHz the vertical frequency 60Hz In the case of random trigger mode the only HD signal is used for external synchronization 3 2 1 It uses it with a normal mode Camera mode SROO 00H CMDMD 0 Oneline output camera 1 unit sR01 004 Input dock MQCKS 0 24 5454M Hz CLKSEL CLKDV 0 CCKDV 0 Detection dock of SYNC SR03 40H MHz Shutter control dock steks OUTBOisth
102. transformation is carried out in the buffer memory block and the VGA output becomes possible Buffer memory is the memory of a FIFO type and only the sequecial access possible The length of the XY direction of the monitor is variablelength Itis abletouseit with the constitution of the free size inside the range of the 1M bytes memory X dot Y line Y Maximum value 640 480 1638 800 600 1310 1024 768 1024 1152 864 910 1280 818 819 The buffer memory is rewritten directly with the image data from a camera and alsois rewritten by the DMA forwarding from a system memory It is not possible to read the contents of this memory from a personal computer You do it with 3 bits of the command bits GETMC GMMD GMSL in the case that you dothe rewriting with the image data from a camera The number of the image data that is input relys on the setting item UNBW VUBW etc Example of setting In the case that the output mode is VGA OVMD 1 1 25 175M Hz It is the frequency suitable for VGA of 640x 480 It sets up it with OCA 2400 2 40MHz It is the frequency suitable for SVGA of 800x 600 It sets up it with 636 3 65 2 It is the frequency suitable for XGA of 1024x 768 It sets up it with OCA 1032 Example of setting In the case that the synthesis output mode is S VGA OVMD 0 VGA SVGA XGA of each horizontal total clock number are set up to the counter In the case that vertical frequency is 60 Hz the horizontal frequency t
103. ve use in accordance with the camera is being prepared with different salein our company Please use it 0000000 Camera cable A the our company style DMC BC A Correspondence camera SONY XC 55 NEC TI 400 480 1200 1250 etc Camera cable B the our company style No DMC BC B Correspondence camera SONY XC ST 30 50 70 NEC TI 400 480 1200 1250 etc Camera cable C the our company style DMC BC C Correspondence camera SONY XC 75 7500 etc 5 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 Camera cable D the our company style DMC BC D Correspondence camera SONY XC HR300 TELI CS3720 etc 3 About user registration 000000000 You are ableto register it with the homepage of our company Or please fax the contents of the following model to the sales department address uiuBuugpuugpapuugpugguuguggppBbppBapBggdududlluu 0000000 User registration 000 0 0 D MICROTECHNICA Co Ltd LH LH BL ELE BE DD DH Maintenance department of Sales department ut FAX 00 0000 0000 OO Dhttp www mi crotechni ca co j p n o mulo 000000 p ee 00 0000 2 po 000 mai E mal f
104. video dock 20 234M Hz 20 245MHZ the horizontal frequency 12 528kHz the vertical frequency 12H z At the time of 2 times speed 24Hz 5 1 1 It uses it with a normal mode 12Hz 24Hz SROO 00H CMDMD 0 One line output camera 1 unit CMRMD 0 GTSMD 0 i RNDST 0 SYCMD 0 TRSM 0 SRO2 30H ITRGM 0 J 1 Input video clock VCO 12Hz 12Hz 20 224MHz 24Hz 24Hz 20 245MHz Detection dock of SYNC SR03 40H EHCKS 1 Shutter control clock STCKS 0 Boa ____ OUTBO is the HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTBI is the VD signal SR06 07H BIOMD1 1 Output signal Negative logic output SRO7 03H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 is the TRG signal BIOMD2 1 Output signal Negativelogic output 5 2 Negative logic H level fixed SMOD2 0 Wide use VCA 283H UNBP A4H UNBW 500 VUBP 02H Vertical effective width 12Hz SR17 400H VUBW 400H 1024 lines 24Hz SR17 200H VUBW 200H 512 lines HDSC 650 Pulsewidth ofHD SRI9 0E HDPW 9IJH Repeatedly rate of VD 12Hz SRIA 414H_ VDSC 414H 1044 lines 24Hz 1 20 VDSC 20AH 522 lines Pulse width of VD SR1B 09H VDPW 9H 27 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 5 1 2 It uses it with a random mode It uses it with a Pulse mode SR00 00H CMDMD 0 One line output camera 1 unit _
105. xed Horizontal effective position Horizontal effective width Vertical effective position Vertical effective width Repeatedly rate of HD Pulse width of HD Repeatedly rate of VD Pulse width of VD When you output the GETC command 80H after above setting it is input 1 screen CMDMD 0 GISMD 0 RNDST 0 SR01 00H SYCMD 0 External sync HD VD STRMD 0 1 SR02 94H MQCKS 0 CLKSEL CLKDV 1 CCKDV 0 2 1 intelace mode ITRGM 0 EVEN field 12 2727 2 SRO3 80H 5 gt 3MHz normal 5 BIOMDO 1 SPOLO 1 SMOD1 1 BIOMD1 1 SPOL1 1 SMOD1 1 BIOMD2 1 SPOL2 0 SMOD2 0 SR05 07H SRO6 03H SR07 03H Output signal Negative logic Camera use Output signal Negative logic Camera use Output signal Positivelogic Wide use SR14 4EH 4 The 78th dot SR15 280H UNBW 280H 640 pixels SR16 0F H VUBP 0FH The 15th line SR18 186H HDSC 186H 390 clocks SR19 3EH SR17 F OH VU BW 240 lines H DPW 3EH 62 clocks SR1A 20DH VDSC 20DH__ 525 lines SR1B 09H VDPW 9H 5 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 1 2 It uses it with therandom shutter mode Field processing Camera mode CMRMD 0 One line output SROO 00H camera 1 unit CMDMD 0 External trigger mode GTSMD 0 Shutter mode RNDST Random shutter SR01 82H 1 Middle speed shutter mode Synchronous mode SYCMD 0 External sync HD VD Shutter trig
106. y rate of VD SR1A 238H VDSC 238H 568 lines Other items are same 5 2 CS3720 camera It is 640x 480 659x 494 progress camera of 2 line output and be possible random shutter Signal that is connected to the board are a video signalx 2 a HD signal a VD signal a TRG signal It is used the external synchronous mode VIDEO1 of a video signal of the camera is connected to A and VIDEO2 is connected to B The scanning switch of the camera sets up it to 21 mode You set ON to the termination of a synchronous signal The video clock 24 5454M Hz the horizontal frequency 31 468kHz the vertical frequency 120 2 the time of 2 line output 29 116 Microtechnica 5 2 1 Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 It uses it with a normal mode The mode switch of a camera is setting 1 120 the shutter switch is setting Camera mode Command mode External trigger mode Shutter mode Synchronous mode Shutter trigger mode Scan mode Catch mode Input video dock Detection dock of SYNC Shutter control dock OUTBOisthe HD signal Negative logic output OUTB1istheVD signal Negative logic output OUTB2 istheTRG signal Negative logic output SROO 11H CMDMD 1 Two line output camera 1 unit 1 SRO2 10H iTRGM O 0 MQCKS 0 24 5454M Hz CLKSEL CLKDV 0 CCKDV 0 SR03 40H 12 BIOMDO 1 SPOLO 1 SMOD1 1 BIOMD1 1
107. ynchronous the camera sets up it to the V reset mode When you output the GETC GMOD command after above setting it is input a screen every an external signal Input signal 18 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 3 3 TI 1200A camera It is 1360x 1035 camera for the industry of 1 300 000 pixels Signal that is connected to the board are a video signal a HD signal a VD signal a TRG signal It is used the external synchronous mode The video dock 28 636M Hz In the case of random trigger mode the only HD signal is used for external synchronization 3 3 1 It uses it with a normal mode SRO0 00H CMDMD 0 Oneline output camera 1 unit EE mode External premaga mue made mode SR01 00H Shutter EMEN made STRMD O0 E Scanmode Cath mode SRO2 04H ITRGM O Input video dock MQCKS 0 VCO CLKSEL 0 28 636M Hz CCKDV 0 Detection dock of SYNC___ SRO3 80H shuts cd steks OUTBOisthe HD signal BIOMDO 1 Output signal Negative logic output SPOLO 1 Negative logic SR05 07H SMOD1 1 Camera use OUTB1istheVD signal SR06 07H BIOMD1 1 Output signal Negative logic output SR07 03H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 istheTRG signal BIOMD2 1 Output signal Negative logic output SPOL2 1 Negative logic H level fixed SMOD2 0 Wide use 19 16 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May
108. z CLKSEL 1 CLKDV 1 CCKDV 0 Detection clock of SYNC SR03 80H EHCKS 2 3M Hz normal Shutter control clock Or STCKS 20 or HDO 63 55u 50 or SR03 82H STOCK 2 252K Hz 3 97y 5 OUTBO is the HD signal BIOM DO 1 Output signal Negative logic output SPOLO 1 Negative logic 5 05 07 SMOD1 1 Camera use OUTB1is the VD signal SR06 83H BIOMD1 1 Output signal Negative logic output SRO7 87H SPOL1 1 Negative logic SMOD1 1 Camera use OUTB2 is the TRG signal BIOMD2 1 Output signal Positive logic output SPOL2 0 Positive logic SMOD2 1 Camera use OUTB7 is the signal BIOMD7 0 Input signal Negative logic IN put SPOL7 2 Theshutter control by SMOD external signal input is B amera use possible DONPISHA Shutter time counter SR1C XXH TRGW XXH Counter setting value HD select Exposuretime 678 S HD 63 55u S x TRGW value 252k select Exposure time 742 S 3 971 S x TRGW value 7 116 Microtechnica Doc No MTPCI DD OM E V1 01 Date 1 May 2003 Rev 1 01 2 2 XC55 camera It is 640x 480 progress camera and be possible a random shutter Signal that is connected to the board are a video signal a HD signal a VD signal a TRG signal It is used the external synchronous mode The video dock 12 2727M Hz the horizontal frequency 15 734kHz the vertical frequency 30Hz 2 2 1 It uses it with a normal mode pee c SROO 00H camera 1 unit Shutter mode RNDST 0 SRO1 00H Synchronous mod
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