QTP 22 - QTP 24
Contents
1. 10 6 QTP 22 FIGURE 7 OTP 24 AND 22 PANELS ccssncssccenncactcnncasssssnvoscseeusescdenseenddeeusunacbeduenscasvessaceesvoastonees 12 FIGURE 8 4 PINS CONNECTOR FOR 24 SUPPLY see e ease eee ean 13 FIGURE 9 2 PINS CONNECTOR FOR 24 SUPPLY eee ee eere ee eee sese ete se 14 FIGURE 10 2 PINS CONNECTOR FOR 24 D C SUPPLY 1 4 14 FIGURE 11 4 PINS CONNECTOR FOR 22 SUPPLY 1 ce sesececesesessese 15 FIGURE 12 2 PINS CONNECTOR FOR 22 6 1 1 16 FIGURE 13 2 PINS CONNECTOR FOR 22 D C SUPPLY 4 eee eee eee ee eese ses ee ce sese cs sesosesse 16 FIGURE 14 RS 232 PIN OUT AND POINT TO POINT CONNECTION EXAMPLE 17 FIGURE 15 RS 422 PIN OUT AND 4 WIRES CONNECTION EXAMPLE eee ee eoo ee eee ense e 18 FIGURE 16 RS 485 PIN OUT AND 2 WIRES CONNECTION EXAMPLE eee ee esee eee ee eo sees esee ee 19 FIGURE 17 RS 485 NETWORK CONNECTION EXAMPLE e ee eese esse2. A NS P O2 pA gt A CA ON A 4 gt EN EN A N 95 4 ER NE ELLEN i NN NN FIGURE 26 KEY DEFAULT CODES ON 24 22 24 Rel 3 80 gt Page 29 grifo ITALIAN TECHNOLOGY QTP 22 TERMINAL KEYS MAP 24 SN FIGURE 27 22 TERMINAL KEYS Page 30 22 24 Rel 3 80 KEYS DEFAULT CODES QTP22 Here are the tables which show the codes that QTP 22 send in serial mode when a key is pressed said codes are those ones listed under default condition i e when no keys have been yet re named EY FWf N 31 grifo ITALIAN TECHNOLOGY CHARACTER VISUALIZATION ON THE DISPLAY QTP 22 and QTP 24 show on board display all the characters having a code included in the range 32 255 20 Hex if it is sent a code not included in this range and this latter is not a command this latter is ignored The characters of the codes in the range 32 127 20 7F Hex correspond to those ones of the standard ASCII table while characters associated to 128 255 80 Hex codes vary depending on the type of the display in
3. Hn REPRE IE EE Boo m ooo Boe TI ca ciui FIGURE 42 FLUORESCENT 20 4 CHARACTERS TABLE 22 24 Rel 3 80 a Page A 7 grifo ITALIAN TECHNOLOGY 8 22 24 Rel 3 80 ITALIAN TECHNOLOGY 0 05 APPENDIX LABELS INSERTION III TII FIGURE 43 24 LABELS SLOTS Note A Unscrew the 4 black screws from the front panel B Take panel out and unscrew the 8 screws and their grey plastic spacers which are placed in the back do not take the printed corcuit out from the keyboard C Now the keyboard is ready for getting the 5 personalization labels see figure 43 D Remount the panel following the previous instructions but on the back way 22 24 Rel 3 80 Page B 1 grifo ITALIAN TECHNOLOGY FiGURE 44 QTP 22 LABELS SLOTS Note A Unscrew the 4 black screws from the front panel B Take panel out and unscrew 8 screws and their grey plastic spacers which are placed in the back do not take the printed corcuit out from the keyboard C Now the keyboard is ready for getting the 2 personalization lab
4. Number reading of 27 110 1B 6E ESC n last storaged message 27 33 67 ESC C 21 43 n mess Storaged message n mess 0 13 ASCII n mess char 0 char 19 ASCII char 0 ASCII char 19 Message reading 7 22 1 21 45 n mess ESC E ASCII n mess Messages visualization BC n mess n n mess n ASCII n mess ASCII n Messages visualization in 27 33 83 21 53 ESC S sliding mode n mess n char n mess n char ASCII n mess ASCII n char Writing of the Badge Reader configuration byte 1 21 42 byte ESC ASCII byte Reading of the Badge Reader configuration byte 27 33 98 21 62 ESC b Badge Reader request of 21 76 iB the acquired string Acquisition of the 27 67 IB 43 ESC C automatic reader status MON 27 33 76 21 4 ESC L reading procedure Card 27 33 101 21 65 ESC e automatic reader Command for EATING the card 27 33 84 21 54 ESC T Clock SET UP 19 21 0 ESC ASCII string string string Clock Clock reading 27 33 102 21 66 ESC f Time visualization on the 27 33 116 21 74 ESC 1 display frm r c frm ASCII r ASCII c ASCII frm Date visualization on the 27 33 100 1B 21 64 ESC d display r c frm r c frm ASCII r ASCII c ASCII frm Writing of a byte of the 27 33 71 21 47 ESC G Real Time Clock RAM addr byte addr byte ASCII addr ASCII byte FIGU
5. ITALIAN TECHNOLOGY 2 PINS CONNECTOR FOR QTP 22 A C SUPPLY FIGURE 12 2 PINS CONNECTOR FOR 22 SUPPLY Signals description 8 24 Vac I Lines for QTP 22 supply through AC voltage connected to the on board switch 2 PINS CONNECTOR FOR QTP 22 D C SUPPLY 5Vdc GND PIT 29 4 FiGURE 13 2 PINS CONNECTOR FOR 22 D C suPPLY Signals description 5 Line for 22 supply through 5Dc voltage GND Ground line for QTP 22 supply Page 16 22 24 Rel 3 80 CONNECTOR FOR SERIAL COMMUNICATION The connector for RS 232 RS 422 485 or Current Loop communication is CN2 on QTP 24 and CN3 on QTP 22 it is question of a 9 pins D female connector Signals location has been carefully studied in orderto reduce to the minimum level the interferences and making easier the connection to the field RS232 CONNECTION CN2 QTP 24 CN3 QTP 22 9 Pin Connector Master Remote System FIGURE 14 RS 232 PIN OUT AND POINT TO POINT CONNECTION EXAMPLE Signals description RxD I Receive Data TxD Transmit Data GND Ground line QTP 22 24 Rel 3 80 Page 17 grifo ITALIAN TECHNOLOGY 4 WIRES RS 422 CONNECTION GND CN2 24 CN3 22 9 Master Remote System FIGURE 15 RS 422 PIN O
6. 22 24 Quick Terminal Panel ER MANUAL m 0 1 Bi O p 15 nd B 8 E LE 00 Via Artigiano 8 6 H B 40016 San Giorgio di Piano g fo Bologna ITALY ITALIAN TECHNOLOGY Email grifo grifo it http www grifo it http www grifo com Tel 39 51 892 052 a r FAX 39 51 893 661 QTP 22 24 Edition 3 80 Rel 05 February 1998 grifo are trade marks of grifo 22 24 Quick Terminal Panel SR MANUAJ 24 Intelligent user panel equipped with Fluorescent 20x2 or 20x4 LCD display LEDs backlit 20x2 or 20x4 characters RS 232 RS 422 485 or Current Loop serial lines serial EEPROM for set up and messages Possibility of re naming keys LEDs and panel name by inserting label with new name into the proper slot 24 keys and 16 LEDs with blinking attribute and Buzzer manageable by software built in power supply RTC option reader of magnetic badge and relays QTP 22 Intelligent user panel equipped with alphanumeric LCD display LEDs backlit 40 1 40x2 or 40x4 characters or alphanumeric Fluorescent display 40x1 40x2 or 40x4 characters RS 232 RS 422 485 or Current Loop serial lines serial EEPROM for set up and messages Possibility of re naming the 22 keys and name panel by inserting label with new name into the proper slot 22
7. 6 6 FIGURE 42 FLUORESCENT 20X4 CHARACTERS TABLE e ee ee ee ee ee eee eee se none see e se se tasses ee eee A 7 FIGURE 43 OTP 24 LABELS SLOTS 2oseeekexenn euk eontekeseuhnvhseckoae B 1 FIGURE 44 OTP 22 LABELS SLOTS B 2 Page IV INTRODUCTION The use of these devices has turned IN EXCLUSIVE WAY to specialized personnel The purpose of this handbook is to give the necessary information to the cognizant and sure use of the products They are the result of a continual and systematic elaboration of data and technical tests saved and validated from the Builder related to the inside modes of certainty and quality of the information The reported data are destined INEXCLUSIVE WAY to specialized users that can interact with the devices in safety conditions for the persons for the machine and for the enviroment impersonating an elementary diagnostic of breakdowns and of malfunction conditions by performing simple functional verify operations in the height respect of the actual safety and health norms The informations for the installation the assemblage the dismantlement the handling the adjustment the reparation and the contingent accessories devices etc installation are destined and then executable always and in exclusive way from specialized warned and educated p
8. APPENDIX DISPLAYS CHARACTERS TABLES Higher 4 bit to 07 of Character Code Hexadecimal z pm 8S revere o o 0 7 8 2526 TE FIGURE 36 LCD 20x2 CHARACTERS TABLE 22 24 _ Rel 3 80 A GEO Lower 4 bit DO to 03 of Character Code Hexadecimal Eun DSL ue mL 528 28 a lt lt ae D gt 1 grifo ITALIAN TECHNOLOGY usa cw ni t6 300090000 JAM Page A 2 22 24 3 80 2 2 3 1 6 6 7 D E P __ ______ _ 7 Ekla l 1 EU 2 3 202 I 91315111 p lt 0 Le fem o 1310 1111 LOWER 4 HEXADECIMAL FIGURE 38 LCD 40 1 AND 40 4 CHARACTERS TABLE Page A 3 22 24 _ Rel 3 80 grifo I
9. 41 COMMANDS FOR DIFFERENT 8 42 Do E E E E 42 RELAY AGTIVATION P 42 RELAY DEACTIVATION aluzion 42 Page 22 24 3 80 READING OF VERSION NUMBER esas aono Fin ien m IE OUS NRI an 42 COMMANDS FOR MESSAGES MANAGEMENT 43 NUMBER READING OF THE LAST STORAGED MESSAGE 43 STORAGED MESSAGE c 43 MESSAGE READING s 44 MESSAGES 225202558 556 RR NINE ERU REIR seb vaca is se 44 MESSAGES VISUALIZATION IN SLIDING 45 COMMANDS FOR BADGE READER 2 21 46 WRITING OF THE BADGE READER CONFIGURATION BYTE 46 READING OF THE BADGE READER CONFIGURATION BYTE 47 SINTAX OF THE STRING ACQUIRED BY THE BADGE 47 BADGE READER REQUEST OF THE ACQUIRED STRING 48 ACQUISITION OF THE AUTOMATIC READER STATUS eere 49 EXECUTION OF A NEW READING PROCEDURE 49 CARD EJECTION FROM AUTOMATIC READER 49 COMMAND FOR EATING THE CARD
10. Mnemonic CR The cursor is placed at the beginning of the line where it is CARRIAGE RETURN LINE FEED Code 29 1D Hex Mnemonic GS The cursor is placed at the beginning of next line at which it was placed If the cursor is at the last display line it will be placed at the beginning of the first line 1 Home position CURSOR ABSOLUTE POSITIONING WITH 20H OFFEST Code 2789rc 1B59 c Hex Mnemonic ESC Y ASCII r ASCII c The cursor is placed at the absolute point indicated through r and c These codes are referred to line and column values of the display at which the 32 20 Hex offset must be add If forexample you wish to place the cursor at Home position 0 line 0 column the next sequence is necessary 27 89 32 32 If line and column values are not compatible to the installed display that command is ignored 22 24 Rel 3 80 Page 33 grifo ITALIAN TECHNOLOGY COMMANDS FOR CHARACTERS ERASURE BACKSPACE Code 08 Mnemonic BS The cursor shifts a character on the left by erasing the contents of the reached cell Ifthe cursoris at Home position the character placed in the last cell down on the right ofthe display will be erased CLEAR PAGE Code 12 0C Hex Mnemonic FF Complete erasure of the display and the cursor returns to Home position CLEAR LINE Code 25 19 Hex Mnemonic EM The complete line where cursor
11. The communication with remote units is standard RS 232 serial line but it can be optionally changed in RS 422 485 or Current Loop 8 Bit protocole communication NO PARITY selectionable Baud Rate among 1200 2400 4800 9600 19200 and 38400 Baud The local set program makes possible to set anumber of 1 or 2 Stop bit As optionis available a communication protocole Master Slave type with 9th bit tecnique and settable Baud Rate at 187 5 Kbaud too RELAYS QTP 22 and QTP 24 can have as option n 1 Relay equipped with 1 Ampere contact This latter can be switched on off via software directly by the user and it makes available on the appropriate connector the contact both normally open and normally closed This option could be necessary when the automatic door opening must be directly controlled by using the terminal placed in the immediate closeness in this case it will be necessary a power driven by the said relay REAL TIME CLOCK QTP 22 and QTP 24 as option can have Real Time Clock 256 Bytes of RAM at user disposal with Lithium battery data back up This device is manageable with appropriate software commands by the user and in this way it is possible to set time and date to read these data or to have them on the display given position There are also available two commands for writing and reading data from the on board RAM of the RTC BADGE READER INTERFACE QTP 22 and QTP 24 as option can have a circuitery that allows t
12. BLINKING BLOCK CURSOR Code 27 81 1B 51 Hex Mnemonic ESC Q The cursor is started so it is visible Now it is a blinking rectangular form and it is alternatively visualized with the char put on the same Note This command is available only for LCD displays otherwise is ignored QTP 22 24 Rel 3 80 Page 35 grifo ITALIAN TECHNOLOGY COMMANDS FOR EEPROM MANAGEMENT REQUEST FOR ON EEPROM WRITING Code 27 51 1B 33 Hex Mnemonic ESC3 This command asks the card if it is ready for writing data on its on board EEPROM This command must be executed any time there are messages to be memorized ot some commands to be sent 6 ACK QTP xx READY 21 15 Hex NACK QTPxx NOT READY If the send back the code it is not yet possible to memorize a new data on EEPROM WRITING OF LIFE BYTE Code 27 33 78 key 1B 21 4E key Hex Mnemonic ESC ASCII key The Life Byte of the card is set with the value indicated in the key parameter this parameter can be included in 0 255 range This byte has a reserved allocation on the on board EEPROM that once it is set with the value desired it allows for example to verify that 22 24 run correctly or if there are some communication problems on the serial line Note This command means a data writing on the on board EEPROM so before executing it is better to verify that the card is read
13. FIGURE 3 24 Page 7 22 24 Rel 3 80 gt n 2 4A 2 TECHNICA MR ON GENERAL FEATURES On board resources On board CPU Communicating protocole Character size PHYSICAL FEATURES Size Weight Mounting Connectors Page 8 grifo _ ITALIAN TECHNOLOGY ly S lt ICA RI TION 5 22 LEDs coupled to keys 22 software reconfigurable keys and available for user s personalization LCD Display 40 characters for 1 2 or 4 lines backlite or not backlite trimmer for contrast regulation or Fluorescent Display 40 characters for 1 2 or 4lines BUZZER for BELL signaling or sound feed back when keys are pressed Full duplex RS 232 serial line or RS 422 485 or Current Loop EEPROM for set up messagges keys codes and so on 4 KBytes maximum Option RTC with 256 Bytes user accessible RAM Option 1A Relay with Changeover contacts Various options among those ones there is also an interface for magnetic cards reader for single track INTEL 87C51 with 14 7456 MHz Quartz INTEL 87C52 with 12MHZ Quartz Option Baud Rate 1200 2400 4800 9600 19200 or 38400 Bauds Option 187 5 Bauds 1 or 2 Stop Bit No Parity Bit standard communication 9 Bit Master Slave communication Option settable communication in Master Slave mode Fluorescent 40x1 5 x 7 dots 3 5 x 5 0 mm Ho
14. eres eee enses enses sustain sto 49 COMMANDS FOR MANAGING THE ON BOARD REAL TIME CLOCK 50 CLOCK SET UP 5 e PR 50 CLOCK READING T qu dan d tocos resora 50 WRITING OF A BYTE OF THE REAL TIME CLOCK 51 READING OF A BYTE OF THE REAL TIME CLOCK RAM 51 TIME VISUALIZATION ON THE DISPLAY 51 DATE VISUALIZATION ON THE 2 52 22 QTP 24 COMMAND CODES SUMMARY 8 4 44 00 lt 53 MASTER SLAVE COMMUNICATION 56 APPENDIX DISPLAYS CHARACTERS 8 10 1 APPENDIX LABELS INSERTION 1 1 1 1 APPENDIX ALPHABETICAL INDEX seran C 1 22 24 Rel 3 80 Page III grifo _ ITALIAN TECHNOLOGY FIGURE INDEX FiGURE 15 24 SE c 5 FIGURE 2 OTP 24 CONSUMPTION TABLE oen EV RE aer Fee 6 FiGURE 3 24 PHOTO P 7 FIGURE HER uer 9 FIGURE 5 22 CONSUMPTION TABLE
15. Current Loop serial reception Receive Data Positive positive bipolar line for Current Loop serial reception Transmit Data Negative negative bipolar line for Current Loop serial transmission Transmit Data Positive positive bipolar line for Current Loop serial transmission For Current Loop connection it is possible to get 2 differents type of connection 2 and 4 wires These kind of connections have been shown in the next two drawings where it is possible to see the voltage for VCL and the resistances for current limitation R The supply voltage vary in compliance with the number of the devices connected When the maximum of current 20 runs it must be guaranted that each device dissipates at maximum 125mW for transmitter and 90mW for receiver The R resistance is needed for limiting the maximum of current in case short circuit of the line This is a 220 Q resistance for a voltage of VCL 5Vdc For further info please referto HEWLETT PACKARD Data Book page for HCPL 4100 and 4200 devices 22 24 Rel 3 80 _ Page 21 grifo ITALIAN TECHNOLOGY CN2 QTP 24 CN3 QTP 22 9 Pin Connector Master Remote System FIGURE 19 4 wires CURRENT LOOP POINT POINT CONNECTION EXAMPLE CN2 24 CN3 22 9 Pin Connector Master Remote System FIGURE 20 2 wires CURRENT LOOP POINT TO POINT CONNECTION EXAMPLE 5 OTP 22 24 Rel 3 8
16. ES n TS FIGURE 6 22 11 22 24 Rel 3 80 _ efle o o o o o w o TERMINALS INSTALLATION This chapter illustrates all the operations which have to be done for the proper use of QTP 22 and QTP 24 terminals These latter are provided with 4 connectors 2 of which are optional for getting all the connections to the system Here under please find the list of their Pin Out and the meaning of the connected signals QTP 24 POWER SUPPLY CONNECTOR isa quick screw terminal connector having 2 or 4 pins as it is possible to get the 5Vdc generated by the on board switch power supply The standard QTP 24 version is supplied with a2 pins connector which is connected for giving a voltage of 8 24Vac or 5Vdc to the card Here is the rear view of the terminal where are shown the possible connector configurations 4 PINS CONNECTOR FOR QTP24 SUPPLY 5 GND 8 24 Vac FIGURE 8 4 PINS CONNECTOR FOR 24 suPPLY Signals description 8 24 Vac I Lines for QTP 24 powering through AC voltage connected to the on board switch section 5 Output line for powering an external load through on board switch power supply GND Ground line for external load supply 22 24 Rel 3 80 _ Page 13 gri
17. EYE 27 24 TERMINAL KEYS enden 28 KEYS DEFAULT CODES ON 24 cus co von s v ge is son s v ruds vend sh bana cista r r s 29 55555295 45 ova Fu QNS ENN ren 30 KEYS DEFAULT CODES ON 22 vincc sor n s vec s c n dat ode sesa v ndi ar nenas ede sesa eds 31 CHARACTER VISUALIZATION ON THE DISPLAY 32 COMMANDS FOR CURSOR POSITIONING 32 CURSOR LEFT m 32 CURSOR RIGHT e c cc on vedi v re sess 32 CURSOR DOWN pr 32 CURSOR UP vesa 33 e E E 33 CARRIAGE RETURN nm siste duan on 33 CARRIAGE RETURN LINE FEED e esee mese eere ense esence seseseseseseseceseseosesesesenessese 33 CURSOR ABSOLUTE POSITIONING WITH 20H OFFEST 0 33 COMMANDS FOR CHARACTERS ERASURE 7 34 34 CLEAR 34 CLEAR edhe r nd ed 34 CLEAR END Id or 34 CLEAR END OF PAGE dro eds d 34 COMMANDS FOR CUR
18. Hex Mnemonic ESC B ASCII byte The byte with the parameters for Badge reader is storaged in the on board EEPROM and kept there even if power voltage fails Therefore QTP 22 or QTP 24 is re configurable for the badge reader management in compliance with the parameters the said byte supplies this configuration wil be restored each time the will be powered and it will maintain this configuration until a new setting byte will be sent The meaning of the said byte is as follows Bit 0 gt 0 The Badge reader connected to the QTP is of the Insertion Type only if the reader is of manual insertion type because if the reader is of automatic insertion type this bit is ignored The Badge reader connected to the QTP is of the Sliding Type Bitl 0 The string memorized on to magnetic card it is acquired when this latter is during the insertion phase in the reader only if the reader is of manual insertion type when reader is manual or of the automatic insertion type this bit is ignored 1 The string memorized on to magnetic card is acquired when this latter is during the disinsertion phase from the reader Bit2 gt 0 The Badge reader connected to the QTP reads Track 1 1 The Badge reader connected to reads Track 2 3 Bit3 gt 0 When a string is acquired from the Badge reader this one is storaged and immediately sent in serial mode This function is not available in Master Slave mode 1 When string is acquired f
19. LED 16 LED 21 only for QTP 22 If a bit is placed in 0 position the correpondent LED is OFF viceversa it will be ON if the correspondent bit is on 1 position If there are some LEDs having the blinking attribute this latter will be desabled P S For QTP 24 the byte3 must be always sent even if it has no meaning for running the 16 LEDs of the said terminal QTP 22 24 Rel 3 80 Page 37 grifo ITALIAN TECHNOLOGY LEDS MAP THE 24 TERMINAL ase FIGURE 29 LEDs OF THE 24 TERMINAL 2 QrP2224 13 80 Page 36 ITALIAN TECHNOLOGY grifo LEDS MAP OF THE QTP 22 TERMINAL 22 FIGURE 30 LEDs OF THE 22 TERMINAL QTP 22 24 Rel 3 80 Page 39 grifo ITALIAN TECHNOLOGY COMMANDS FOR KEYBOARD MANAGEMENT KEY RECONFIGURATION Code 27 55 keyno code 1B 37 key no code Hex Mnemonic ESC 7 ASCII key no ASCII code When the selected key is reconfigured each time it is pressed the card will send the new specified code in serial mode The number of the key to be reconfgured is obtainable by looking at the QTP picture and it must be included in a range of 0 27 0 1B Hex if this is not done the command is ignored The code val
20. QTP 22 consumption referred to the different versionswhich install different displays version These consumptions are referred to the QTP 22 basic version with no options Consumption Consumption DISPLAY Model IEDs Switched LEDs Switched 400 mA 5 Vdc Not Backlite LCD 0 4 W 8 24 Vac 2 5 W 8 24 410 mA 5 Vdc 75 miA 5 Vde Backlite 40x1 LCD 2 6 8 24 Vac 4 1 W 8 24 Vac 5 Vde 5 Vide Backlite 40x2 LCD 2 6 8 24 Vac 4 7 W 8 24 Vac 810 mA 5 Vdc 1150 mA 5 Vdc 5 1 W 8224 Vac 7 2 W 8 24 Vac 345 495 mA 5 4 585 735 5 22 3 W 8 24 3 7 4 6 W 8 24 Vac 795 1045 mA 5 Vdc 1135 1385 mA 5 Vdc 526 5 W 8 24 Vac 7 18 7 W 8 24 nm 1445 2045 mA 5 1785 2385 mA 5 MES 9 12 W 8 24 Vac 112149 W 8 24 Vac 5 22 CONSUMPTION TABLE Backlite 40x4 LCD 40x2 Fluorescent Page 10 22 24 Rel 3 80 ITALIAN TECHNOLOGY 0 09 67 40x1 FLUORESCENT DISPLOV 22 KEVS 22 0 05 5 FLUORESCENT DISPLAV 22 KEVS 22 LEDS 688657 3BUZZER NNESSAGES 48 CHRRRCTERS 4E IHES FLUORESCENT DISPLRV 5232 485 16066864 5656 IL i k SPOVERSSUPPLY BUILTIN E WU 22 ors VITHIZ2SLEDSI tIBUZZERSANDILABELS mae uv Ca
21. RS 422 485 or Current Loop EEPROM for set up messagges keys codes and so on 4 KBytes maximum Option RTC with 256 Bytes user accessible RAM Option 1A Relay with Changeover contacts Various options among those ones there is also an interface for magnetic cards reader for single track On board CPU INTEL 87C51 with 14 7456 MHz Quartz INTEL 87C52 with 12MHZ Quartz Option Communicating protocole Baud Rate 1200 2400 4800 9600 19200 or 38400 Bauds Option 187 5 Bauds 1 or 2 Stop Bit No Parity 8 Bit standard communication 9 Bit Master Slave communication Option settable communication in Master Slave mode Character size Fluorescent 20x2 5 x 7 dots 2 25 x 4 16 mm Horiz Vertical Fluorescent 20x4 5 x 7 dots 2 40 x 4 70 mm Horiz Vertical LCD 20x2 5 x 7 dots 3 20 x 4 85 mm Horiz Vertical LCD 20x4 5 x 7 dots 2 95 x 4 75 mm Horiz Vertical PHYSICAL FEATURES Size please refer to figure n 1 Weight 1000 grammes max Mounting On panel as Front panel and Back panel or direct mounting on Phoenix CombiCard industrial housings Page 4 22 24 Rel 3 80 2 4 pins quick scew connector for power CN2 9 pins female D connector for serial connection CN3 3 pins quick screw connector for relays connection Option CN4 10 pins connector for differents expansions such as Card reader Option Temperature range from 0 to 5
22. any key of the 22 24 in order to avoid complication in recognizing begginning of the answering string Ifthis association cann t be avoided itis possible to discriminate the string answering from the badge reader by checking the time break that elaps from the arrival of these codes The third byte of the string is named cod It contains the info concerning the result of the acquisition just performed in particular way Bit 7 gt 1 It shows that the saved info are transmitted for the first time 0 It shows that the saved info have been transmitted at least one time therefore no additional magnetic cards have been acquired The management of this bit is necessary because when a string 15 acquired by the badge reader through the specific command it can be asked for various time so it is necessary to discriminate if the received answer concernes a new acquisition or it is question of a repetition of the previous one Obviously if the QTP is set for transmitting the answer immediately during the first reception of the string autonomously transmitted by the terminal same the result is that said bit will be always at 1 Bits 0 6 gt of cod byte have on the contrary the following meaning Bits 0 6 gt 0 Into memory none string availabe at present 6 A string valid and complete has been received 2 Astring has been received but CRC is not correct or START char is omitted 26 Valid string has been rece
23. can be linked to just to get the KeyClick function EEPROM QTP 22 and QTP 24 have the on board EEPROM the capacity vary from 256Bytes to 4 KBytes for memorizing set up keys code communication protocole name messagges and so on It is possible to memorize up to 202 messages of 20 characters to be read in different moments or visualing them on the display just giving the identifying number of the message to the terminal Page 2 22 24 Rel 3 80 22 and 24 have respectively a keyboard of 22 and 24 keys These keys are equipped with AutoRepeat and they are totally software re configurables as the code sentin RS 232 can be changed when a key is pressed It is also possible to switch on off the KeyClick function 1 6 the Buzzer function each time a chosen key is pressed Keyboards have user s reconfigurable slots for keys re name the QTP 22 has 22 re naming keys while QTP 24 has 16 re naming keys INDICATOR LEDS 22 and 24 have indicator LEDs for different visual signals On 24 there are 16 LEDs and on QTP 22 there are 22 LEDs all of them can also have the Blinking attribute as this function is totally autonomous and it doesn t need any interventation on user part The QTP 22 has LEDs linked to all its 22 keys while QTP 24 has 12 LEDs linked to keys and the remaining 4 keys are for user s personalization SERIAL COMMUNICATION
24. will begin the answering phase Baud Rate Time Out 187500 Baud 110 38400 550 19200 990 9600 1540 4800 3080 2400 6105 1200 12100 When the Time Out is over xx begins answering phase which consists a byte containing the code of the pressed key FF Hex none key is pressed or a data string related to a reading command sent in the previous request For example if a string containing the reading command ofthe version is transmitted we will get that for this particular request pressed key code will be sent back while in the next one the number of the required version previously asked for will be transmitted After that the last char of the string has been transmitted to the QTP xx it will be necessary to wait a time of char transmission time Time Out before reaching the first char of the answering string transmitted by the QTP 22 or QTP 24 For example if we are working at 187 5 Baud when the transmission of the last char has been completed it is necessary to wait for about 160 before completening the reception of the first answering byte on QTP xx part Between a call and the next one it is necessary to wait for a time that is related to the number of commands sent and type of operations these latter ones involve Page 56 22 24 Rel 3 80
25. 0 Relative humidity 2096 up to 9096 without condense QTP 24 OVERALL SIZE Here is the QTP 24 size in mm Rear view and lateral sides where connectors are located This is not a scale drawing 114 5 FIGURE 1 24 SIZE 22 24 Rel 3 80 _ Page 5 grifo ITALIAN TECHNOLOGY ELECTRICAL FEATURES Power voltage 5Vdc or 8 24 External loads power 5Vdc option Power supply power 7 5 W RS 422 485 Termination Network pull up resistor Absent pull down resistor Absent line termination resistor 120 Hereunder islisted the QTP 24 consumption referred to the different versionswhich install different displays version These consumptions are referred to the QTP 24 basic version with no options Ma Consumption Comsumption Vlodlell LEDs Switched LED Ds Switched 5 Vde 300 mA 5 Vdc NOT Backlite LCD 0 3 W 8 24 Vac 19 W 8 24 Vac 200 mA 5 Vdc 450 mA 5 Vdc 1 3 W 8224 Vac 2 8W 8 24 Vac 250 mA 5 Vdc 500 mA 5 Vdc 1 6 W 8224 Vac 3 1 W 8224 Vac 295 395 mA 5 Vdc 545 645 mA 5 Vdc 1 8 2 5 8 24 Vac 3 4 4 W 8 24 Vac FIGURE 2 24 CONSUMPTION TABLE 22 24 Rel 3 80 Page 6 22 2 LCD 3025 16LEDS BUZZER E M5 a m 2 Lu ai 3 o 0 EEPROM 2 a 24KEYS 16LEDS BUZZER d 15 6 KA TEREN
26. 0 Page 22 CONNECTOR FOR RELAY CONNECTION The connector for the on board relay connection option is named CN3 on 24 and 4 QTP 22 Itis a3 pins quick terminal connection on itthere are the following contacts nomal open normal close and commun ofthe Relay as shown in the drawings here under QTP 24 rear side and QTP 22 profile view FicunE 21 24 RELAY CONNECTOR FIGURE 22 22 RELAY CONNECTOR Signals description Comun Relay commun contact N C Relay contact normal closed N O Relay contact normal open Page 23 QTP 22 24 Rel 3 80 4 grifo ITALIAN TECHNOLOGY CONNECTOR FOR CARD READER CONNECTION This optional connector is a 10 pins 2 54 mm type Itis named CN9 on QTP 22 and CN4 on QTP 24 Its pin out depends from the card reader type manual or motor driven and below there is a description of the 2 different pin outs MANUAL BADGE READER CONNECTION OPEN 1 2 OPEN 3 Switch 3 RDP 5 5 7 ee Vdc 9 GND FIGURE 23 CONNECTOR FOR MANUAL CARD READER Signals description OPEN This pin must be necessary NOT CONNECTED RDP Pintobeconnectedto Read Data Pulse signal d
27. 3 80 ACQUISITION OF THE AUTOMATIC READER STATUS Code 27 67 1B 43 Hex Mnemonic ESC C A byte containig some status info card inside motor ON ect is sent back This byte has the following values 0 gt card inside the badge reader and motor is OFF 1 gt reader has a card inside and motor is OFF 2 gt card inside and motor is ON This code is sent back for example during the inizializing phase of the reader itself after a power on of the QTP or while the card is EATEN 3 gt The reader has a card inside and motor is ON This code is sent back for example during the card reading or during insertion ejection phases of the same 255 gt The badge reader is of manual type or the management of the card device is OFF EXECUTION OF A NEW READING PROCEDURE Code 27 33 76 1B 21 4C Hex Mnemonic ESC L A new reading procedure of the card inside the automatic badge reader is executed If there are other operations on the same device or the QTP is configured for the manual reader this command is ignored Note Each card reading procedure include 3 attempts max if a mistake in acquiring the same occurs CARD EJECTION FROM AUTOMATIC READER Code 27 33 101 1B 21 65 Hex Mnemonic ESC e The ejection of the card inside the automatic badge reader is executed This command is ignored when a no card inside the reader b other operations are taking place on the device c the QTP is con
28. ESC k Cursor OFF 27 80 B 50 ESC P Static cursor ON 27 79 B 4F Blinking Underline 27 77 1B 4D ESC M cursor Blinking Block 27 81 51 ESC cursor FiGURE 33 COMMAND CODES SUMMARY TABLE 1 22 24 Rel 3 80 _ Page 53 grifo _ ITALIAN TECHNOLOGY f TDN 7 OL CO J MIT Mi D BIEX C 00 27 50 32 LED Activation ASCII n LED n LED Attr n LED Attr ASCII Attr ESC 4 ASCII bytel ASCII byte2 ASCII byte3 Relay Activation 27 56 1B 38 ESC 8 Relay Deactivation Deactivation 27 37 B 39 ses 9 EEPROM writing ss 27 33 Er Writing of life byte 78 key 21 4E key ASCII key Reading ofife byte Reading ofife byte life byte 27 33 110 1B 21 6E Characters show 32 255 20 FF space ASCII 255 Keyclick ON without 27 53 1B 35 ESC 5 memorization Keyclick OFF without 27 54 1B 36 ESC 6 memorization 27 55 5 7 Key reconfiguration Keyclick ON with 27 33 53 21 35 ESC 5 memorization Keyclick OFF with 27 33 54 2136 ESC 6 memorization Reading of version 27 86 56 ESC V number FiGURE 34 CODES SUMMARY TABLE 2 22 24 3 80 LEDs Mask 27 52 bytel 1B 34 Activation byte2 byte3 bytel byte2 byte3 Page 54
29. F THE STRING ACQUIRED BY THE BADGE READER 47 Size 4 8 Slots 2 STATIC CURSOR ON 35 Stop Bit 3 4 8 27 STORAGED MESSAGE 43 Page C 4 22 24 Rel 3 80 ITALIAN TECHNOLOGY grifo T Temperature range 5 9 TERMINALS 2 TERMINALS INSTALLATION 13 TIME VISUALIZATION ON THE DISPLAY 51 Weight 4 8 WRITING BYTE 36 WRITING OF THE BADGE READER configuration byte 46 22 24 Rel 3 80 _ Cabaco 3613 Page C 5 grifo ITALIAN TECHNOLOGY Page 22 24 Rel 3 80
30. FIGURE 17 RS 485 NETWORK CONNECTION EXAMPLE On the network line the user must connect a pull up and a pull down resistor 3 3 because they are not present on QTP 22 and QTP 24 terminals The user must also remember to connect at the communication line extremes 2 line termination resistors 120 2 installed respectly nearthe Master unit and near the farthest Slave unit The 120 Q line termination resistor is already available on 22 and QTP 24 and can be connected or not to the network with a dedicated jumper 22 J5 gt Connected DEFAULT The 120 Q line termination resistor is connected to the RS 485 line Not connected The 120 Q line termination resistor is not connected to the RS 485 line QTP 24 J3 gt Connected DEFAULT The 120 Q line termination resistor is connected to the RS 485 line Not connected The 120 Q line termination resistor is not connected to the RS 485 line For further info please refer to RS 422 and RS 485 Interface Circuits TEXAS INSTRUMENTS Data Book pages for RS 422 and RS 485 NETWORK 22 24 Rel 3 80 Page 20 ITALIAN TECHNOLOGY esse 87582 CURRENT LOOP CONNECTION Signals description RX Curr Loop I Curr Loop TX Curr Loop TX Curr Loop Curr Loop RX Curr Loop FIGURE 18 CURRENT Loop PIN OUT Receive Data Negative negative bipolar line for
31. LEDs with blinking attribute and Buzzer manageable by software built in 24 Vac power supply RTC option reader of magnetic badge and relays Via dell Artigiano 8 6 40016 San Giorgio di Piano g r I to Bologna ITALY ITALIAN TECHNOLOGY Email grifo grifo it http www grifo it http www grifo com Tel 439 51 892 052 FAX 39 51 893 661 QTP 22 24 Edition 3 80 Rel 05 February 1998 GPC grifo are trade marks of grifo DOCUMENTATION COPYRIGHT BY grifo ALL RIGHTS RESERVED No part of this document may be reproduced transmitted transcribed stored in a retrieval system or translated into any language or computer language in any form or by any means either electronic mechanical magnetic optical chemical manual or otherwise without the prior written consent of grifo IMPORTANT Although all the information contained herein have been carefully verified grifo assumes no responsibility for errors that might appear in this document or for damage to things or persons resulting from technical errors omission and improper use of this manual and of the related software and hardware grifo reservs the right to change the contents and form of this document as well as the features and specification of its products at any time without prior notice to obtain always the best product For specific informations on the components mounted on the card please refer to the Data Book of the builder or s
32. NAGEMENT 37 COMMANDS FOR MANAGING THE ON BOARD REAL TIME CLOCK 50 COMMANDS FOR MESSAGES MANAGEMENT 43 Communicating protocole 4 8 CONNECTOR FOR CARD READER CONNECTION 24 CONNECTOR FOR RELAY CONNECTION 23 CONNECTOR FOR SERIAL COMMUNICATION 17 Connectors 5 8 5 8 13 CN2 5 8 15 17 CN3 5 9 17 23 4 5 9 23 24 CN9 24 CPU 4 8 Current Loop 2 3 4 8 17 21 CURRENT LOOP CONNECTION 21 CURSOR ABSOLUTE POSITIONING WITH 20H OFFEST 33 CURSOR DOWN 32 CURSOR LEFT 32 CURSOR OFF 35 CURSOR RIGHT 32 CURSORUP 33 D DATE VISUALIZATION ON THE DISPLAY 52 E EEPROM 2 3 4 8 36 43 EXECUTION OF NEW READING PROCEDURE 49 External loads power 6 10 F FIRMWARE RELEASE 1 Fluorescent 2 4 8 H HOME 33 I INSTALLATION 13 Page C 2 22 24 Rel 3 80 K KEY 40 KEY RECONFIGURATION 40 KEYBOARD 27 KEYCLICK 3 27 40 KEYCLICK OFF WITH MEMORIZATION 41 KEYCLICK OFF WITHOUT MEMORIZATION 40 KEYCLICK ON WITH MEMORIZATION 41 KEYCLICK ON WITHOUT MEMORIZATION 40 Keys 2 3 4 8 KEYS DEFAULT CODES 24 29 KEYS DEFAULT CODES 22 31 L LCD 2 4 8 LED activation 37 LEDs 2 3 4 8 26 37 LEDs of the 22 TERMINAL 39 LEDs of the 24 TERMINAL 38 LEDs MASK activation 37 Lithium 2 LOCAL SETUP 26 M MANAGING PROGRAMM WITH MASTER SLAVE COMMUNICATION 27 MANAGING PROGRAMM WITHOUT MASTER SLAVE COMMUNICATI 26 Manual BADGE
33. ONNECTOR FOR 22 0 16 CONNECTOR FOR SERIAL 24 17 RS 232 CONNECTION p 17 4 WIRES RS 422 CONNECTION eaa inna 18 2 WIRES RS 485 CONNECTION 19 RS 485 MASTER SLAVE COMMUNICATION 20 CURRENT LOOP CONNECTION sci vp cvoucsosaoasasuatenniadeucasaxes ceoveceuasasacuecenstevaneuss 21 CONNECTOR FOR RELAY 22 2 2 2 23 CONNECTOR FOR CARD READER 2 2 2 24 MANUAL BADGE READER 2 24 MOTOR DRIVEN BADGE READER CONNECTION 25 22 24 Rel 3 80 44 4409 ITALIAN TECHNOLOGY SOFTWARE DESCRIPTION 26 hedhe ada ad duan hd dan t nn 26 MANAGING PROGRAM WITHOUT MASTER SLAVE COMMUNICATION 26 MANAGING PROGRAM WITH MASTER SLAVE COMMUNICATION 27 KEYBOARD ACQUISITION uu ve cec v rod v s ec n en s eds deles di nd cuba de tha r nd v n EE
34. RE 35 COMMAND CODES SUMMARY TABLE 3 22 24 Rel 3 80 _ Page 55 grifo ITALIAN TECHNOLOGY MASTER SLAVE COMMUNICATION MODE The Master Slave mode uses the 9 bits communication technique In addition to the 8 data bit also a 9th bit is managed as it is needed for recognizing between a call coming from the Master to any of the Slave structures and a simple info transmission between Master and the selected device When 9th bit is placed at 1 the data byte have to contain the name or identifying code of the device towards it needs to communicate while by placing this particular bit at 0 position it is possible to take out or supply with info at this device As far as communications QTP 22 and QTP 24 the identifying code must be that one set by the local Set up programm of the terminal itself When this byte is sent with 9th bit placed at 1 position the QTP xx recognizes itself and it waits the string containing chars data or commands this string must be of 25 bytes max In this string there must only be a comand that involves the return of an information sent via serial line on QTP xx part if there 15 an higher number the remaining commands of these type are ignored Between the transmission of a char and the next one there must be an interval of time shorter than the Time Out as elapsed this delay the QTP xx will consider the data string ended and it
35. SOR ATTRIBUTES MANAGEMENT 35 CURSOR M 35 5 5555 35 BLINKING UNDERLINE CURSOR sissies snsicstsenssacsnssossatsniannstsseosecdesensscssnessuedenzensadvecss 35 BLINKING BLOCK CURSOR on n 35 COMMANDS FOR EEPROM MANAGEMENT 1 36 REQUEST FOR ON EEPROM WRITING 36 WRITING OF LIFE BYTE sot s uka 36 READING OF LIFE BY TE 25555 8 36 COMMANDS FOR LEDS 2 2 2 1 37 LED ACTIVATION nm 37 LEDS MASK ACTIVATION tn b r nudos edanc t sara edukon se 37 LEDS MAP OF THE 24 TERMINAL 2 esence sesesesesosesecesessosesescesese 38 LEDS MAP OF THE 22 TERMINAL sissvesccosecseasenteoasatsnrsscnsssoosectsosnsseusnesanctenratssevecse 39 COMMANDS FOR KEYBOARD MANAGEMENT 40 KEY RECONFIGURATION r n s v abs dam gua als Phan rr b n dado soda cis a edu 40 KEYCLICK ON WITHOUT MEMORIZATION 40 KEYCLICK OFF WITHOUT MEMORIZATION 4 99 40 KEYCLICK ON WITH MEMORIZATION 2 enses sns 41 KEYCLICK OFF WITH MEMORIZATION
36. T STORAGED MESSAGE Code 27 110 1B 6E Hex Mnemonic ESCn The number of the last storaged message is sent back in serial mode it varys in compliace with the EEPROM quantity installed on the card please refer to the below table EEPROM IE PROMIT icc SIZE NI SIZE 256 Bytes 2304 Bytes 512 Bytes 2560 Bytes RC 2048 Bytes 4096 Bytes FiGURE 31 NUMBER MESSAGES STORAGEABLE ON EEPROM STORAGED MESSAGE Code 27 33 67 mess no char 0 char 19 1B 21 43 mess no char 0 char 13 Hex Mnemonic ESC C ASCII mess no ASCII char 0 ASCII char 19 The 20 char message with code indicated as mess no is stored in on board EEPROM The 20 char which form the message must be visualized on the display so thet are included in a range of 32 255 20 Hex otherwise the command is ignored The message number must be included in the range of O max no where max no is the number of the last storaged message just previously described P S This command needs a data writing in on board EEPROM so before executing it be sure that the card is ready for the new writing on that device otherwise the command will be ignored QTP 22 24 Rel 3 80 Page 43 grifo ITALIAN TECHNOLOGY MESSAGE READING Code 27 33 69 mess no 1B 21 45 mess no Hex Mnemonic ESC E ASCII mess no The 20 char message corresponding to mess it
37. TALIAN TECHNOLOGY 1 1 1 1 1 1 NI 3 Emi 141121314151 5121213 AIBICIDIE rein peje rp Rasen totos a xU EA et Sher Wet t net 4 0 g 1 1 1 1 051 1 IHHHHH M 1 1234567 E pa Eeee R e iex o el FIGURE 40 FLUORESCENT 40 1 AND 40 2 CHARACTERS TABLE 2224 Rel 3 80 Page 5 ITALIAN TECHNOLOGY grifo abaco e 0001 1 910 DiM DC4 18 118 0111 1080 BS 1001 1018 110 1 1 FIGURE 41 FLUORESCENT 40 4 CHARACTERS TABLE Rel 3 80 X N N Q Page A 6 ITALIAN TECHNOLOGY grifo OOUOUU Boro 55555 O O E BICDE BRET FEEL EERE EI eee aE be E eh i 58 BEBE EISE Es pelear epe Ep e EER 0 5 2
38. URES sida duo dhe GERE van dolen 4 24 OVERALL SIZE 5 ELECTRICAL FEATURES 5005 5555 v n 6 QTP22TECHNICAL SPECIFICARTIONS 8 GENERAL FEATURES an os oda vala kave n dd ed dua sa ede ass 8 5 50555 dd ha ev v n id duna haha ela SCR GENE kod dha es bee durt 8 22 OVERALL SIZE 9 5 95 10 TERMINALS INSTALLATION 13 QIP24 POWER SUPPLY CONNECTOR 13 4 PINS CONNECTOR FOR 24 SUPPLY 13 2 PINS CONNECTOR FOR 24 SUPPLY 14 2 PINS CONNECTOR FOR 24 D C SUPPLY 2 1 14 22 POWER SUPPLY lt 15 4 PINS CONNECTOR FOR 22 SUPPLY 15 2 PINS CONNECTOR FOR 22 SUPPLY 16 2 PINS C
39. UT AND 4 WIRES CONNECTION EXAMPLE Signals description RX Receive Data Negative negative bipolar line for 4 wires RS 422 485 diversity serial reception Receive Data Positive positive bipolar line for 4 wires RS 422 485 diversity serial reception TX Transmit Data Negative negative bipolar line for 4 wires RS 422 485 diversity serial reception Transmit Data Positive positive bipolar line for 4 wires RS 422 485 diversity serial reception GND Ground line 22 24 Rel 3 80 Page 16 2 WIRES RS 485 CONNECTION TX RX TX GND TX RX CN2 QTP 24 CN3 QTP 22 9 Pin Connector Master Remote System FIGURE 16 RS 485 PIN OUT AND 2 WIRES CONNECTION EXAMPLE Signals description Receive Transmit Data Negative negative bipolar line for diversity serial transmitting or receiving 2 wires RS 422 485 RX TX Receive Transmit Data Positive positive bipolar line for diversity serial transmitting or receiving 2 wires RS 422 485 GND Ground line Note Using this serial connection it is possible to get the 9 Bit Master Slave communication mode only 22 24 Rel 3 801 Page 19 grifo ITALIAN TECHNOLOGY RS 488 MASTER SLAVE COMMUNICATION NETWORK Master Slave 1 22 24 Unit GND Slaven QTP 22 24 Unit
40. ata line coming from the reader RCP Pin to be connected to Read Clock Pulse signal clock line coming from badge reader CPS be connected to the Card Presence signal coming from the badge reader SWITCH This pin must be connected only if a manual insertion reader is used and in particular way this pin must be connected to N O contact of the switch for this reader type only Jas it indicates that the card is inserted even if partially The COM contact of the said switch must be necessarly connect to the CND Vdc 5Vdc voltage for badge reader supply GND Ground line to be connected to badge reader GND Page 24 22 24 Rel 3 80 ITALIAN TECHNOLOGY grifo _ MOTOR DRIVEN BADGE READER CONNECTION D 8 81 RDP RCP 52 OPEN 2 GND FIGURE 24 CONNECTOR MOTOR DRIVEN CARD READER Signals description OPEN This pin must be necessary NOT CONNECTED MRS Pin to be connected to the Motor Reverse signal coming from badge reader MFS Pin to be connected to the Motor Forward signal coming from badge reader RDP Pinto connected to Read Data Pulse signal data line coming from the badge reader and relative to the used track RCP Pinto be connected to the Read Clock Pulse signal clock line coming from the badge reader and relative to the used track S1 Pin to be connecte
41. d to the Badge reader signal which is driven by the switch indicating that the card is inserted into its slot 52 Pin to be connected to Badge reader signal which is driven by switch indicating that the beginning edge of the card is lined up to the reading head GND Ground line to be connected to the badge reader GND NOTE Ifthe QTP is configured for the motor driven badge reader connection the maximum EEPROM size is 2 Kbytes and the Real Time Clock can t be managed QTP 22 24 Rel 3 80 Page 25 grifo ITALIAN TECHNOLOGY SOFTWARE DESCRIPTION As already said QTP 22 and QTP 24 terminals are complete video terminals and for this reason any thing received through serial line if it is not question of a command is shown on the display and codes of any pressed keys of the on board keyboard are transmitted to the control master unit On board of these terminal panels is also implemented a local set up program which allows to set the communication protocole by using the QTP s keyboard and display This manual contains in addition to the description of the different functions a complete list of the comand sequences and the recognized combination to be used to benefit of the main features of QTP 22 and QTP 24 For each code or codes sequence there is a double description i e the mnemonic one through the ASCII characters and the numerical one under decimal and hexd
42. day of the week which are drawn from the on board Real Time Clock The meaning of these bytes is the same listed in figure n 32 22 24 Rel 3 80 Page 50 WRITING OF A BYTE OF THE REAL TIME CLOCK RAM Code 27 33 71 addr byte 1B 21 47 addr byte Hex Mnemonic ESC ASCII addre ASCII byte On board Real Time Clock RAM byte it is written with the value shown in byte The address where memorize the said byte is shown at addr and it must be included in the range 32 255 20 FF Hex otherwise the command is ignored READING OF A BYTE OF THE REAL TIME CLOCK RAM Code 27 33 71 addr 1B 21 47 addr Hex Mnemonic ESC g ASCII addr The on board Real Time Clock RAM byte placed at the address shown at 15 sent back via serial line This byte must be included in the range 32 255 20 FF Hex otherwise the command is ignored TIME VISUALIZATION ON THE DISPLAY Code 27 33 116 c frm 1B 21 74 frm Hex Mnemonic ESC t ASCII r ASCII c ASCII frm The time drawn from the on board Real Time Clock is displayed starting from the position shown by the r and c bytes These codes express the raw and column values of the display at which an off set of 32 20 Hex must be added If the raw and column values are not compatible to the display installed this command will be ignored The frm parameter is used to specify the visualization format in particular way Bit0 1 The time is visua
43. e Master unit with the format illustrated in the specific paragraph The AutoRepeat function of the pressed key is also implemented so when QTP recognizes the pressure on a specific key for a period of time over 0 5 sec it will start the serial transmission of its code for about 0 2 sec and it lasts until that specific key is left again These two pictures show the keys numbering of QTP 22 and QTP 24 then the two tables show the codes the terminal leaves again in serial mode after having pressed a key As per the command sequences these ones are expressed under decimal form hex decimal and mnemonic formats by means of the specific characters of the ASCII table 22 24 Rel 3 80 _ Page 27 grifo ITALIAN TECHNOLOGY QTP 24 TERMINAL KEYS MAP 1 2 34 SIS Ay OTP 22 24 Rel 3 80 Page 28 ITALIAN TECHNOLOGY KEYS DEFAULT CODES ON QTP 24 esse 87582 Here are the tables which show the codes that QTP 24 send in serial mode when a key is pressed said codes are those ones listed under default condition i e when no keys have been yet re named 4 4 4 N 4 95 gt m bz CA CA AN N N N EN E N gt N gt
44. e ignored The frm parameter is used to specify the visualization format in particular way Bit0 1 The date is visualized and automatically managed in position 0 The visualization of the date is interrupted Bit 1 gt 1 The format that visualizes the date is as follows MM DD YY i e MM month DD day YY year 0 The format that visualizes the date is as follows DD MM YY i e DD day MM month YY year Bit 2 7 gt 0 Reserved for future expansion They must be set to 0 value Please note that the weerk day is not managed For example if you wish to visualize the date starting from Home position 0 raw 0 column and in MM DD YY format it will be necessary to send the following sequence 27 33 110 32 32 3 Note The date drawn is managed in background and so there is a slowing down of serial data interpretation This is the reason why it is necessary to wait for few msec between the transmission of 20 30 bytes data blocks In this way misunderstanding in interpreting the received data is completely void Page 52 22 24 Rel 3 80 22 QTP 24 COMMAND CODES SUMMARY TABLES COMMAND CODE EX CODE MNEMONIC o om 9 p ww 9 o E CURSORUP UP O CRLF Cursor absolute ESC Y ne 20H 27 89 Ing de ASCII 8 CLEARLINE LINE diE LINE 27 75 1 4 ESC K CLEAR END OF PAGE 27 107 1B 6B
45. ecimal form The said commands respect the ADDS View Point standard so all the sequences begin with ESC character corresponding to the 27 decimal code 1B Hex LOCAL SETUP At this point the display shows the parameter set up menu and LEDs referred to the keys used for modifying the parameters become active more exactly it is necessary to act on keys n 5 and n 6 as it will be lately illustrated Take note that if QTP is equipped with the managing program for Master Slave communication Option there will be a bigger number of option at your disposal and for this reason please refer to the paraghraph which refer to the managing program installed on the terminal same MANAGING PROGRAM WITHOUT MASTER SLAVE COMMUNICATION KEY n 5 It allows to select the parameter to be modified displaying the following menu BAUD communication Baud Rate STOP Stop bits number and Keyclick function KEY n 6 It allows to vary the value of the parameter previously selected with key n 5 and the following selections can be made BAUD 38400 19200 9600 4800 2400 or 1200 Baud STOP 1 1 Stop bit or 2 2 Stop bits ON Keyclick or OFF Keyclick Once the set up ends pressing keys n 0 and n 11 together the parameters are memorized and it goes back to the standard function Page 26 22 24 Rel 3 80 MANAGING PROGRAM WITH MASTER SLAVE COMMUNICATION KEY 5 It allows the sel
46. econd sources SYMBOLS DESCRIPTION In the manual could appear the following symbols Attention Generic danger Attention High voltage Trade marks grifo are trade marks of grifo Other Product and Company names listed are trade marks of their respective companies ITALIAN TECHNOLOGY GENERAL INDEX INTRODUCTION e 1 FIRMWARE 1 TERMINALS GENERAL FEATURES cucivesovosiscean c e tera Ue YU Cu EH eaa ea ache 2 0 G 2 EEPROM 2 KEYBOARD 55 3 INDICATOR LEDS T 3 SERIAL COMMUNICATION g cc s inerte p sas do sos t s qin tav ce sec 3 RELAYS cin edi an nd dan ht ed n ve ve 3 e NR 3 BADGE READER INTERFACE ITE od n d 3 ON BOARD POWER SUPPLY GENI on 3 24 TECHNICAL SPECIFICATIONS Ga es sea zos cin ions Tedd sea s cn ena a cuo aS 4 GENERAL FEATURES 5558 d r n dd add dd nd n s an s k do nda i 4 PHYSICAL PERAT
47. ection of the parameter to be modified displaying the following menu COMMUNICATION communication type BAUD RATE communication baudrate STOP BIT Stop bits number KEYCLICK Keyclick function NAME first digit and NAME second digit KEY n 6 It allows to vary the value of the parameter previously selected with key n 5 and the following selections can be made COMMUNICATION Standard or Master Slave BAUD RATE 187500 38400 19200 9600 4800 2400 or 1200 Baud STOP BIT 1 or 2 with standard communication 1 with Masetr Slave communication KEYCLICK ON or OFF NAME it modifies the figure from gt and lt in the field 0 Hex Please note that the code that will be put in it will be the same to be used for identifying the QTP 22 or QTP 24 in Master Slave communication Once the set up ends if key n 0 and n 11 are pressed at the same moment the parameters are memorized and it returns to the standard function 5 To this set up program it is possible to enter only at moment of switch on if keys n 0 and n 11 are pressed during standard QTP 22 and QTP 24 running no results will be achieved KEYBOARD ACQUISITION When QTP 22 or QTP 24 recognizes the key pressure it transmits the pertinent code in serial mode and this is immediate if standard communication is used When Master Slave communication is used the said code is re sent only upon specific request of th
48. eese sesa sec oeste toss sete ease see 20 FIGURE 18 CURRENT LOOP PINSOUT Lii eeteeeskscae esuo ens asina etae cavae pace 21 FIGURE 19 4 wires CURRENT LOOP POINT TO POINT CONNECTION EXAMPLE 4 1 22 FIGURE 20 2 wires CURRENT LOOP POINT TO POINT CONNECTION EXAMPLE 22 FIGURE 21 24 RELAY CONNECTOR ssccissvesscoseccsssasscssncocecesensscsesenendcsessanecdenenacescssanseeeveaneesese 23 FIGURE 22 22 RELAY CONNECTOR 23 FIGURE 23 CONNECTOR FOR MANUAL CARD READER e esee ee eee eene een nonno 24 FIGURE 24 CONNECTOR FOR MOTOR DRIVEN CARD READER 25 FIGURE 25 24 TERMINAL KEYS MAP sscccscsvesscactssnsassscsncestcesevescsessnensssecsenacsesenacaseesenseeeveansesess 28 FIGURE 26 KEY DEFAULT CODES ON 24 44 ee ee nese nese sesa ette sose se cesesececesesessese 29 FIGURE 27 22 TERMINAL KEYS ninecci ioercese ve on nb nabh acne sesi Cre 30 FIGURE 28 KEY DEFAULT CODES ON 22 c esence nese eee eee enne ee eet sese sene sene se sesesecesesesossese 31 FIGURE 29 LEDs OF THE 24 TERMINAL eee ee ee eee eee enne ee eee se sec tat
49. els see figure 44 D Remount the panel following the previous instructions but on the back way E label indicated by the arrow is default inserted 22 24 Rel 3 80 Page B 2 APPENDICE ALPHABETICAL INDE Simboli 2 WIRES RS 485 CONNECTION 19 2 WIRES CURRENT LOOP 22 4 WIRES RS 422 CONNECTION 18 4 WIRES CURRENT LOOP 22 A ACQUISITION OF THE AUTOMATIC READER STATUS 49 ADDS View Point 2 26 AutoRepeat 27 B Backlite 2 BACKSPACE 34 BADGE 46 BADGE READER 2 46 BADGE READER INTERFACE 3 BADGE READER REQUEST OF THE ACQUIRED STRING 48 Baud Rate 3 4 8 27 BEEP 42 BELL 2 BLINKING block CURSOR 35 BLINKING underline CURSOR 35 BUZZER 2 4 8 CARD EJECTION FROM AUTOMATIC READER 49 Cards reader 4 8 24 25 CARRIAGE RETURN 33 CARRIAGE RETURN LINE FEED 33 Character size 4 8 CHARACTER VISUALIZATION ON THE DISPLAY 32 CLEAR END OF LINE 34 CLEAR END OF PAGE 34 CLEAR LINE 34 CLEAR PAGE 34 CLOCK READING 50 CLOCK SET UP 50 COMANDS FOR CURSOR POSITIONING 32 COMMAND FOR EATING THE CARD 49 COMMANDS FOR BADGE READER MANAGING 45 COMMANDS FOR CHARACTERS ERASURE 34 COMMANDS FOR CURSOR ATTRIBUTES MANAGEMENT 35 22 24 Rel 3 80 _ Page C 1 grifo ITALIAN TECHNOLOGY COMMANDS FOR DIFFERENT FUNCTIONS 42 COMMANDS FOR EEPROM MANAGEMENT 36 COMMANDS FOR KEYBOARD MANAGEMENT 40 COMMANDS FOR LEDs MA
50. end 27 33 66 14 the string acquired by QTP will be received only if QTP will be asked for it by using the specific command P S This command needs a data writing in on board EEPROM so before executing it be sure that the card is ready for the new writing on that device otherwise the command will be ignored READING OF THE BADGE READER CONFIGURATION BYTE Code 27 33 98 21 62 Hex Mnemonic ESC b The byte having the Badge reader configuration connected to the QTP 22 or QTP 24 is sent in serial mode The meaning of this byte is the same one seen previously By this command it is so possible to know in any moment what is the configuration of QTP 22 or QTP 24 SINTAX OF THE STRING ACQUIRED BY THE BADGE READER When the Badge reader acquires the magnetic card the QTP 22 or QTP 24 storages the info coming fron this reading and if it is OK also the char contained in the card If the QTP is set for sending immediately via serial line these info Bit 3 ofthe set byte placed at position the following string will be transmitted C2 Hex C2 Hex cod char no char 1 charn 0D Hex 0A Hex The first two characters of the said string is CZ Hex code repeated twice it is needed to indicate that the next info are pertinent to the Badge reader It would be useful that this code is not associated 22 24 Rel 3 80 _ Page 47 grifo ITALIAN TECHNOLOGY to
51. entire range of display commands including Clear Screen Position cursor LED blink etc with code compatibility similar to that of the ADDS ViewPoint video terminal Maximum specifications for the QTP are Surface or flush panel mounting Mounting direct to Phoenix CombiCard industrial instrument cases Professional keypad 22 keys and 22 LEDs QTP22 or 24 keys and 16 LEDs QTP24 Complete user reconfiguration of key codes Direct control of all indicator LEDs blinking command on indicator LEDs Name personalization slots label for keys Panel name personalization slot Alphanumeric display options afforded by Fluorescent or LCD Buzzer programmable as BELL or to sound with keystroke EEPROM for permanent storage of set up messages key codes etc Maximum possible EEPROM capacity 4 Kbytes Option 1 A relay with changeover contacts serially controlled Option interface for magnetic strip badge reader Option RTC with 256 bytes user accessible RAM and Lithium backup battery RS 232 RS 422 485 or Current Loop serial line Local selection of Baud Rate Internal power supply capable of driving external loads DC or AC power supply from 5 to 24 Vac Customized keyboard and program packages BUZZER QTP 22 and QTP 24 have a circuitery ables to emit a steady sound based on a capacitive buzzer The said circuitery can be activated via software through a specific comand for generating a sound or it
52. ersonnel or directly from the TECHNICAL AUTHORIZED ASSISTANCE in the height respect of the builder recommendations and the actual safety and health norms The devices can t be used outside a box The User must always insert the cards in a container that rispect the actual safety normative The protection of this container is not threshold to the only atmospheric agents but specially to mechanic electric magnetic etc ones To be on good terms with the products is necessary guarantee legibility and conservation of the manual also for future references In case of deterioration or more easily for technical updates consult the AUTHORIZED TECHNICAL ASSISTANCE directly To prevent problems during card utilization itis a good practice to read carefully all the informations of this manual After this reading the User can use the general index and the alphabetical index respectly at the begining and at the end of the manual to find information in a faster and more easy way FIRMWARE RELEASE This handbook make reference to firmware release 2 0 standard version with uP 87c51 5 8 extended version with 87 52 and following ones The validity of the information contained in this manualis subordinated to the firmware release number so the user must always verify the correct correspondence beetween the notations Inside the device the firmware release number is written on the label stuck on the CPU or it can be obtained by a proper com
53. figured for the manual reader COMMAND FOR CARD Code 27 33 84 1B 21 54 Hex Mnemonic ESC T The card inside the badge reader is eaten it goes out from the back of the reader itself just to drop it into its basket This operation is executed only if the corrispondent bit in the configuration byte is cleared bit 620 This command is ignored when a no card inside the reader b other operations are taking place on the device c the QTP is configured for the manual reader QTP 22 24 Rel 3 80 Page 49 grifo ITALIAN TECHNOLOGY COMMANDS FOR MANAGING THE ON BOARD REAL TIME CLOCK CLOCK SET UP Code 27 33 70 0 byte 6 byte 21 46 Obyte 6 byte Hex Mnemonic ESC ASCII 0 byte ASCII 6 byte The on board Real Time Clock is set with the data contained in the bytes named 0 byte 6 byte if one of these ones has a value included in the allowed range the RTC allocation is not programmed Here under is listed the meaning of the 7 bytes of above and their allowed range 0 0 59 MINUTES 0 59 SECONDS 1 31 DAY 1 12 MONTH Week day 0 gt SUNDAY 6 gt SATURDAY FIGURE 32 7 BYTES FUNCTION FOR REAL TIME CLOCK SETTING CLOCK READING Code 27 33 102 1B 21 66 Hex Mnemonic ESC f The 7 bytes named 0 byte 7 byte are sent back via serial line with the date time and
54. fo ITALIAN TECHNOLOGY 2 PINS CONNECTOR FOR 24 SUPPLY 8 24 FIGURE 9 2 PINS CONNECTOR FOR 24 SUPPLY Signals description 8 24 Vac I Lines for QTP 24 supply through Ac voltage connected to on board switch 2 PINS CONNECTOR FOR QTP 24 D C SUPPLY 5 Vde GND FIGURE 10 2 PINS CONNECTOR FOR 24 D C supply Signals description 5 Line for 24 supply through 5Dc voltage GND Ground line for QTP 24 supply Page 14 22 24 Rel 3 80 22 POWER SUPPLY CONNECTOR CNZ2 isa quick screw terminal connector having 2 or 4 pins as it is possible to get 5Vdc generated by the on board switch power supply The standard 22 version is supplied with a 2 pins connector which is connected for giving a voltage of 8 24 or 5Vdc to the card Here are the possible configuration of the said connector 4 PINS CONNECTOR FOR QTP22 SUPPLY 5 8 24 Vac N FIGURE 11 4 PINS CONNECTOR FOR 22 50 Signals description 8 24 Vac I Lines for QTP 22 supply through AC voltage connected to the on board svvitch section 5 Output line for powering an external load through on board switch power supply GND Ground line for external load supply QTP 22 24 Rel 3 80 Page 15 grifo
55. is placed is erased and then the cursor goes at the beginning of the said line CLEAR END OF LINE Code 27 75 1B 4B Hex Mnemonic ESCK characters on the line where the cursor 15 placed are erased starting from cursor position up to the end of the line The cursor stays on the position as it was when Clear End of Line code arrives If for example the cursor is at the beginning of a display line the complete line will be erased CLEAR END OF PAGE Code 27 107 1B 6B Hex Mnemonic ESC k characters starting from the Cursor point up to the end of the display are erased The cursor stays in the same position as it was before the Clear end of Page code arrival If for example the cursor is at Home position the display will be completaly erased 22 24 Rel 3 80 Page 34 COMMANDS FOR CURSOR ATTRIBUTES MANAGEMENT CURSOR OFF Code 27 80 1B 50Hex Mnemonic ESC P cursor is not active and it is not more visible STATIC CURSOR ON Code 27 79 1B 4F Hex Mnemonic ESC O The cursor is started so it is visible Now it is a not blinking line placed under the char Note this command is not available if Futaba 40x4 display is installed BLINKING UNDERLINE CURSOR Code 27 77 1B 4D Hex Mnemonic ESCM The cursor is started so it is visible Now it is a blinking line placed under the char Note This command is available only for Futaba displays 20x2 and 40 1 type
56. is read by the EEPROM and sent in serial mode beginning from the first char of the string At the end of the message CR LF codes are sent but if the is set for Master Slave function the said codes are not more sent The message number must be included in the range of 0 max no where max no is the number of the last storaged message just previously described If this number is not compatible with the EEPROM quantity installed on the QTP this command is ignored MESSAGES VISUALIZATION Code 27 33 68 mess no n 1B 21 44 mess no n Hex Mnemonic ESC D ASCII mess no ASCII n On the display 20 char messages are visualized beginning from cursor position The first of the n messages is that one having the code correspondng to mess no while the remaining messagges are those ones immediately subsequents in EEPROM The number of mess no must be included in the range of 0 max no where has the same meaning we have previously seen in figure n 31 If this numberis not compatible with the EEPROM quantity installed on the QTP this command is ignored The quantity of messages to be visualized depends only on the model of the display and it is included in these ranges 20 2 or 40 1 Display n between 1 2 20x4 or 40x2 Display n between 134 40x4 Display n between 1 8 If n value is not compatible with the model of the installed display the command is ignored The cursor is
57. ived but END char is omitted When manual insertion badge reader type is used the string is considered valid only if START and END chars have been indentified therefore the QTP is configuretd for such reader type and QTP will never send back the 26 code as the magnetic card must be always throughly acquired If itis question of an insertion reader it is possible to get a partial card acquisition for this reason the string is considered valid even if the END char is not identified The forth byte of the answering string named n char contains the number of the chars acquired by the magnetic card which will follow the answering string expect for the last chars CR LF If the acquired string is not valid that byte will contain 0 value and it will be only followed by CR LF codes On the contrary if the magnetic card is correctly acquired after the byte named n car ASCII codes of chars contained in the card will follow between START and END codes As said above the answering string will end with CR LF codes BADGE READER REQUEST OF THE ACQUIRED STRING Code 27 76 1B 4C Hex Mnemonic ESC L The answering string is sent via serial line with the sintax already described If QTP 22 or QTP 24 is set for communicating in Master Slave mode the answering string will not count CR LF chars This command is available also when QTP is configured for sending the acquired string to the Badge reader Page 48 22 24 Rel
58. lized and automatically managed in c position The visualization of the time is interrupted 1 gt 1 The time is visualized in AM PM format HH MM SSm 1 HH hours MM minutes SS seconds m or 0 The time is visualized in 24H format HH MM SS i e HH hours MM minutes SS seconds Bit 2 7 gt 0 Reserved for future expansion They must be set to 0 value For example if you wish to visualize the time starting from Home position 0 raw 0 column and in 24 H format it will be necessary to send the following sequence 27 33 116 32 32 1 Note The time drawn is managed in background and so there is a slowing down of serial data interpretation This is the reason why it is necessary to wait for few msec between the transmission of 20 30 bytes data blocks In this way misunderstanding in interpreting the received data is completely void QTP 22 24 Rel 3 80 Page 51 grifo ITALIAN TECHNOLOGY DATE VISUALIZATION ON THE DISPLAY Code 27 33 100 r c frm IB 21 64 r c frm Hex Mnemonic ESC d ASCII r ASCII c ASCII frm The date drawn from the on board Real Time Clock is displayed starting from the position shown by the r and c bytes These codes express the raw and column values of the display at which an off set of 32 20 Hex must be added If the raw and column values are not compatible to the display installed this command will b
59. mand sent through the serial line 22 24 Rel 3 80 _ Page 1 grifo ITALIAN TECHNOLOGY TERMINALS GJENIERAJL FEATURES 22 Quick Terminal Panel 22 Keys and 24 Quick Terminal Panel 24Keys are complete operator panels specifically designed for industrial use and for direct mounting on automatic machinery They are in every respect video terminals suitable to be the direct interface between operator and machinery in any of the control or comand operations which could be necessary during running or diagnostic of the same QTP are available with Fluorescent or LCD displays backlite or not 20x2 or 4 lines QTP 24 or 40 characters for 1 2 or 4 lines QTP 22 The affords 22 or 24 keys with full user reconfiguration and name personalization slots labels identifying all or some keys Some keys are provided with indicator LEDs which can be switched on and off by dedicated commands received through the serial line A third slot label can be used to carry a name for the QTP or the user s own logo The basic QTP can be expanded utilizing the various options available namely EEPROM up to 4 Kbyte capacity Real Time Clock with 256 bytes user accessible RAM and Lithium backup battery Actuating relay piloted through serial line Acquisition from magnetic badge reader Sundry communication protocols Custom operating programs etc The QTP is able to execute an
60. o interface the terminal to a single track magnetic card reader which can be insertion or sliding types for reading the track n 1 2 or 3 22 and 24 automatically acquire the and its decodification while the string is memorized into the local memory in this way the user receives the message already decodified without being obliged to make further operations ON BOARD POWER SUPPLY QTP 22 and QTP 24 have their own switch power supply so they can be powered with a voltage up to 24 Vac As option the 5Vdc voltage generated by this power supply can be used to power small external loads directly from the terminal same Take note that QTP 22 and QTP 24 instead of this switch power supply can also be supplied with a circuitery which allows to power the said terminals with a 5Vdc voltage 22 24 Rel 3 80 _ Page 3 grifo ITALIAN TECHNOLOGY 24 TECHNICAL SPECIFICATIONS GENERAL FEATURES On board resources 16 LEDs 4 of which are for user s personalization and 12 coupled to keys 24 software reconfigurable keys 12 of which are for user s personalization LCD Display 20 characters for 2 or 4 lines backlite or not backlited trimmer for contrast regulation or Fluorescent Display 20 characters for 2 or 4 lines BUZZER for BELL signaling or sound feed back when keys are pressed Full duplex RS 232 serial line or
61. o see e enses esee 38 FIGURE 30 LEDs OF THE 22 TERMINAL ee ee ee ee eee eee enne ee ce eee ease eee 39 FIGURE 31 NUMBER OF MESSAGES STORAGEABLE ON EEPROM eere eee eee eene eese 0 43 FIGURE 32 7 BYTES FUNCTION FOR REAL TIME CLOCK SETTING eee eee eee ee ee eee enne eee enne eene 50 FIGURE 33 COMMAND CODES SUMMARY TABLE 1 eee eee eee eee eee eren teta esee teen 53 FIGURE 34 COMMAND CODES SUMMARY TABLE 2 se ce se ses se cases cesesessese 54 FIGURE 35 COMMAND CODES SUMMARY TABLE 3 eee ee eaten eee tato sese etta sese e ease eee 55 FIGURE 36 LCD 20x2 CHARACTERS TABLE d A 1 FIGURE 37 LCD 20x4 AND 40 2 CHARACTERS TABLE 4 eee eto sese teta sese ette A 2 FIGURE 38 LCD 40x1 AND 40 4 CHARACTERS TABLE 4 enne ee ece sec ce se toss ette 3 FIGURE 39 FLUORESCENT 20X2 CHARACTERS 5 4 FIGURE 40 FLUORESCENT 40 1 AND 40 2 CHARACTERS TABLE e ee ee eo eo oe ee ee ee eee eee eee e 5 FIGURE 41 FLUORESCENT 40 4 CHARACTERS 5
62. placed in the next cell of the last message visualized if the last char of the said message occupies last position of the display the cursor will be placed in Home position For example if you wish to visualize the message no 20 and 21 it will be necessary to send the following sequence 27 33 68 20 2 to the card P S Visualization of messages on Futaba displays takes some time and it varys depending on the display size Here there are some visualization time of a number of messages which occupy the whole Futaba display 20 2 or 40 1 Display 2 messages 8 msec about 20x4 or 40x2 Display 4 messages 16 msec about 40x4 Display 8 messages 32 msec about Page 44 22 24 Rel 3 80 MESSAGES VISUALIZATION IN SLIDING MODE Code 27 33 83 mess no n char 1B 21 53 mess no n char Hex Mnemonic ESC S ASCII mess no ASCII n char This command visualizes a n char message on the display first line the characters appears in sliding mode The message is shifted from right to left and so the user can visualize a very long string on the display The string of n char characters begins with the first character of the mess no message already stored in EEPROM The mess no value must be included in the range 0 where max no has the same meaning described in figure 31 If the value is out of range this command is ignored The n char parameter is used as follow 0 S
63. reader connection 24 Master Slave communication 4 Master Slave communication 8 19 26 56 MESSAGE READING 44 MESSAGES VISUALIZATION 44 MESSAGES VISUALIZATION in sliding mode 45 Motor driven BADGE reader connection 25 N NAME 27 Network 20 NUMBER READING OF THE LAST STORAGED MESSAGE 43 P 3 4 8 Phoenix 2 4 8 Powersupply 2 3 13 15 Power supply power 6 10 Power voltage 6 10 22 24 Rel 3 80 Page C 3 grifo _ ______ ITALIAN TECHNOLOGY Q QTP 22 OVERALL SIZE 9 QTP 22 Consumption table 10 22 photo 11 22 POWER SUPPLY CONNECTOR 15 QTP 22 RELAY connector 23 QTP22size 9 QTP 22 TERMINAL KEYS MAP 30 QTP 24 OVERALL SIZE 5 QTP 24 and QTP 22 panels 12 24 Consumption table 6 QTP 24 photo 7 QTP 24 POWER SUPPLY CONNECTOR 13 QTP 24 RELAY connector 23 QTP24size 5 QTP 24 TERMINAL KEYS MAP 28 R RAM 4 8 READING OFLIFE BYTE 36 READING OF A BYTE OF THE REAL TIME CLOCK RAM 51 READING OF THE BADGE READER CONFIGURATION BYTE 47 READING OF VERSION NUMBER 42 Real Time Clock 2 3 Relative humidity 5 9 Relay 4 8 23 42 RELAY activation 42 RELAY deactivation 42 REQUEST FOR ON EEPROM WRITING 36 RS 232 2 3 4 8 17 RS 232 CONNECTION 17 RS 422 485 2 3 4 8 17 18 19 RS 422 485 Termination Network 6 10 RS 485 MASTER SLAVE COMMUNICATION NETWORK 20 RTC 2 3 4 8 50 5 5 26 SINTAX O
64. riz Vertical Fluorescent 40x2 5 x 7 dots 3 5 x 5 0 mm Horiz Vertical Fluorescent 40x4 5 x 7 dots 3 0 5 0 mm Horiz Vertical LCD 40x1 5 x 10dots 3 15 x 7 90 mm Horiz Vertical LCD 40x2 5 x 7 dots 3 20 x 5 55 mm Honz Vertical LCD 40x4 5 x 7 dots 2 78 x 4 89 mm Honz Vertical please refer to figure n 4 1800 grammes max On panels as Front panel and Back panel or direct mounting on Phoenix CombiCard industrial housings CNI 2 4 pins 90 quick screw connector for power CN2 9 pins female D for serial connection 22 24 Rel 3 80 3 pins quick screw connector relays connection Option CN4 10 pins connector for differents expansions such as Card reader Option Temperature range from 0 to 50 Relative humidity 2096 up to 9096 without condense QTP 22 OVERALL SIZE Here is the QTP 22 size in mm Rear view and lateral sides where connectors are located This is not a scale drawing Breaking for INPUT Connectors FIGURE 4 22 SIZE 22 24 Rel 3 80 _ Page 9 grifo ITALIAN TECHNOLOGY ELECTRICAL FEATURES Power voltage 5Vdc or 8 24Vac External loads power 5Vdc Option Power supply power 12 5 RS 422 485 Termination Network pull up resistor Absent pull down resistor Absent line termination resistor 120 Hereunder islisted the
65. rom Badge reader this one is only storaged and sent in serial mode only when the QTP receives the specific command 46 22 24 Rel 3 80 Bit 4 0 The magnetic card is inserted into the badge reader starting from its beginning only if the reader is of Manual Insertion Type when the reader is of sliding or automatic type this bit is ignored 1 magnertic card is inserted into Badge reader starting from its end The badge reader is of Manual type The badge reader is of Automatic type 0 Possibility of EATING the card ON only if the reader is of automatic type when the reader is of manual type this bit is ignored 1 Possibility of EATING the card OFF only if reader is of automatic type when the reader is of manual type this bit is ignored The badge reader management is ON 1 The badge reader management is OFF Bit 5 gt Bit 7 gt When the management of the automatic badge reader is ON will execute inizialization of the device itself by acting the motor in a Reverse mode for abaut 0 5 seconds just to eject a card may be kept inside For example if you wish to configure the QTP for managing the Insertion Badge Reader which acquires the track 2 having the readingof the card during the disinsertion phase it will be necessary to send the following sequence 27 33 66 6 for getting a prompt response from If you s
66. stalled This 15 the reason why is better to refer to A Table The character is visualized in the at the moment cursor position and this latter will go the the next position if itis placed in the last character down on the right of the display it will be placed on Home position COMANDS FOR CURSOR POSITIONING CURSOR LEFT Code 21 15Hex Mnemonic NACK The cursor is shifted of one position on the left without modifying the display contents If the cursor is in Home position it will be placed in the last character at the down right position of the display CURSOR RIGHT Code 06 Mnemonic ACK The cursor is shifted of one position on the right Ifthe cursor is placed on the last display character down right il will be place on the Home position CURSOR DOWN Code 10 Hex Mnemonic LF The cursor will be placed on the next line of that one it is now but it will remain in the same column If the cursor is in the last display line it will be placed at the first display line Page 32 22 24 Rel 3 80 CURSOR 26 Mnemonic SUB The cursor will be place din the previous line ot that one it is now but it will remain in the same column If the cursor is on the first display line it will be place on the last display line HOME Code 01 Mnemonic SOH The cursor is on Home position i e first line first column of the display CARRIAGE RETURN Code 13 0D Hex
67. the command will be ignored KEYCLICK OFF WITH MEMORIZATION Code 27 33 54 21 36 Hex Mnemonic ESC 6 The KeyClick function is desabled so there is not sound feedback when a key is pressed This parameter is storaged in the on board EEPROM even if the power voltage fails 5 The said command needs a data writing on on board EEPROM so before executing it it is better to be sure that the card is ready for a new writing on such device otherwise the command will be ignored 22 24 Rel 3 80 _ Page 41 grifo ITALIAN TECHNOLOGY COMMANDS FOR DIFFERENT FUNCTIONS BEEP Code 07 Menomonic BEL buzzer is enabled for 1 10 second time RELAY ACTIVATION Code 27 56 B 38 Hex Mnemonic ESC 8 The relay on card if any is enabled and normal open contact is shut N O and normal shut contact is open N C RELAY DEACTIVATION Code 27 574 1B 39 Hex Mnemonic ESC9 The relay on the card if any is desabled and the normal shut contact is shut N C and the normal open contact is open N O READING OF VERSION NUMBER Code 27 86 B 56 Hex Mnemonic ESC V In serial mode is sent back a string of 3 char containing the program managing version resident on board of QTP 22 or QTP 24 Page 42 22 24 Rel 3 80 COMMANDS FOR MESSAGES MANAGEMENT NUMBER READING OF THE LAS
68. tops the message visualization in sliding mode 20 200 gt Sliding string length when 20 characters for line display is installed 40 200 gt Sliding string length when a 40 characters for line display is installed If n char valueis out ofthe specified ranges or it points after the last character stored in EEPROM the command will be ignored The message visualization in sliding mode is positioned on the first display line and the cursor position and attributes are held For example if you wish to visualize a 23 characters string in sliding mode formed by the fifth message 1 e 20 characters and by the sixth message 3 characters it will be necessary to send the following sequence 27 33 83 5 23 Note The message visualization in sliding mode is managed in background and so there is a slowing down of serial data interpretation This is the reason why it is necessary to wait for few msec between the transmission of 20 30 bytes data blocks In this way misunderstanding in interpreting the received data is completely void 22 24 Rel 3 80 Page 45 grifo ITALIAN TECHNOLOGY COMMANDS FOR BADGE READER MANAGEMENT QTP 22 and QTP 24 terminals are able to acquire single track magnetic badge readers These latter can be both insertion and manual types able to read track n 1 2 or 3 QTP by means of a specific command can be set in compliance with the badge reader at
69. ue can vary in a range of 0 254 0 Hex as the 255 value FF Hex indicates that the key must be desabled so when itis pressed the QTP will not send any codes in serial mode P S The said command needs a data writing on the on board EEPROM so before executing it it is better to be sure that the card is ready for a new writing on such device otherwise the command will be ignored KEYCLICK ON WITHOUT MEMORIZATION Code 27 54 1B 35 Hex Mnemonic ESC 5 The KeyClick function is switched on so there is a sound feedback when a key is pressed This parameter is not storaged in the on board EEPROM so if card is re set it goes back to the previous condition KEYCLICK OFF WITHOUT MEMORIZATION Code 27 54 1B 36 Hex Mnemonic ESC 6 The KeyClick function is desabled so there is not sound feedback when a key is pressed This parameter is not storaged in the on board EEPROM so if the card is re set it goes back to the previous condition Page 40 22 24 Rel 3 80 KEYCLICK ON WITH MEMORIZATION Code 27 33 53 B 2135 Hex Mnemonic ESC 5 The KeyClick function is switched on so there is a sound feedback when a key is pressed This parameter is storaged in the on board EEPROM even if the power voltage fails 5 The said command involves a data writing on board EEPROM so before executing it it is better to be sure that the card is ready for a new writing on such device otherwise
70. which it is connected When QTP is configured to manage the automatic Badge Reader it can manage 2 Kbytes of EEPROM max instead of 4 Kbytes and it can not manage the Real Time Clock These last options are so installable on QTP 22 or QTP 24 only if these terminals do not manage the Badge Reader When the card is inserted into the Automatic Badge Reader slot the QTP automatically acquires the string there contained More specifically the forward motor is activated until the card has been read and the followed string interpreted If a mistake in reading occurs other two attempts of acquisition will take place before declaring that string not valid during this phase the reverse motor is activated in order to re position the initial part of the card to be read for the new reading Once the reading procedure is over the result of such reading is memorized and sent in serial mode as it happens when it is question of the manual badge reader The card stays inside the badge reader until the ejection command is sent The QTP has a further command that allows to eat the card more exactly the forward motor is activated up to the card goes out from the back side of the reader Just to have the card dropped into the little basket This command is executed only when the flag ofthe configuration byte is abled Here below there are the commands for managing such structures WRITING OF THE BADGE READER CONFIGURATION BYTE Code 27 33 66 byte 1B 21 42 byte
71. y for the next writing on that device otherwise the command is ignored READING OF LIFE BYTE Code 27 33 110 1B 21 6E Hex Mnemonic ESC The QTP xx send back in serial mode the value of its Life Byte This command can be useful if you have to verify the presence or the correct running of the card Page 36 22 24 Rel 3 80 COMMANDS FOR LEDS MANAGEMENT LED ACTIVATION Code 27 50 n LED 32 n LED Hex Mnemonic ESC 2 ASCII n LED ASCII Attr The LED shown in n LED with the specified attribute in is started If you use the 24 card LEDs numbers are included in a range of 0 15 as shwon in the picture of the card while for 22 the LEDs numbers are included in a range of 0 21 The attributes available aare as follows 0 Not enabled LED 255 FF Hex Enabled LED 85 55Hex Blinking LED ex If you wish to enable LED n 5 with blinking attribute the following sequence has to be sent 27 50 5 85 If the parameter with LED number or that one with the attribute it is not valid the command is ignored LEDS MASK ACTIVATION Code 27 52 bytel byte2 byte3 1B 34 bytel byte2 byte3 Hex Menomonic ESC 4 ASCII bytel ASCII byte2 ASCII byte3 24 and 22 LEDs contemprarly managed as indicated in bytel byte2 and byte3 following this code bytel bit 0 7 LED 0 LED 7 byte2 bit 0 7 LED 8 LED 15 byte3 010 5
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