CS224802B1 - Controller for interface with medium - Google Patents

Description

The invention relates to a controller for an environmental interface unit which is connected to an IMS-2 instrument interface and operates in binary code.

Known wiring of the control unit connected to the IMS-2 instrument interface uses ASCII code for both control and transmission of data

When processing multiple channels, it is always necessary to send the address of the respective channel first and then the command to perform the required operation · If the range of the measured analog signal is limited, the timing circuit must be set first to control the start of the analog-to-digital converter. amplifiers. All these necessary steps of the JSP control program with known controller connections affect both the time required to set the required parameters and the time per channel measurement *

Significantly shortening of these times and other advantages is the connection of the JSP controller according to the invention, which consists in the fact that it consists of contact circuits, whose first contact inputs are connected to the IMS-2 interface. environmental interface units, third input with first control output of data output control circuit and first input of operation start circuit, fourth input with second control output of β interface, with first circuit input 2 · subaddresses and first circuit input 1 · subaddresses, fifth input with analog-to-digital converter start circuit output and first environmental interface unit input, six inputs DO 1 to DO 8 with data output circuit data output, and seventh input with first address of analog-to-digital address converter circuit output, with second interface unit input and a first environment Their first data outputs Dl i to Dl 8 are connected to the first inputs of the binary code decoder, to the first inputs of the memory inputs

224 802

- 2 data, with first addressing circuit input, second inputs of subaddress 1 and second inputs of second subaddress, their second, control output is connected to second input of binary code decoder, third, control output to first input of data input control circuits and fourth, control output with the first input of the data output control circuits · The first binary code decoder output is connected to the second addressing circuit input, the second, the output to the third circuit input 1 · subaddress, the third, the output to the third circuit input 2 · subaddresses, fourth, output with first injection of single-byte mode control circuit, fifth, control output with second input of single-byte mode control circuit, sixth, control output with second input of data input control circuits, seventh, control output with second input of operation start circuit and third input it is connected to the first, blocking output of the circuits Data Input Controlling · Single-byte mode control output is coupled to the third input of the input control circuit, the third input to the start of the operation circuit, and the second input to the data output control circuit, while the second control output of the 1st byte of the data input control circuit is connected to the fourth input. subaddress 1, with fourth circuit 2 input, subaddress, with second input data input and fourth operation start input and third, control output 2 · byte is connected to fifth input of subaddress 1 circuit, with fifth input of circuit 2, · The sixth input of the operation start circuit is connected to the third output of the external interface of the environment unit, the seventh input with the second control output of broadcast 2, the byte of the data output control circuit, and the first input of the circuits. data outputs and their output is associated with the third input o · The third inputs of the analog-to-digital converter start circuits are connected to the first outputs of the 1 ad sub-address circuit ranges and to the third inputs of the interface unit, while the sixth the sub-address circuit input 1 is coupled to the fourth control output of the sub-address circuit 2, and the second channel address outputs are coupled to the fourth inputs of the environmental interface unit, the fifth inputs of which are connected to the input data outputs Bl 0 to Bl 15 of the input data memory; inputs with second address outputs of addressing circuits, seventh inputs with first outputs circuit function 2 · subaddress, eighth input with second output of channel sampling 2 · aubadres and ninth input with third output of circuit board sampling 2 · subaddresses

- 3,224,802 and The fourth output data outputs BO0 to BO15 are coupled to the second inputs of the data output circuit, the third input of which is coupled to the third, control output of the 1 " byte data "

The advantage of connecting the controller for the JSP according to the invention is that the control and data transmission in both directions is performed via the IUS-2 interface in binary code. All parameters (instrument functions and commands) can be set, including give·

It is sufficient to send 3 or 2 bytes of control data for some boards to set the parameters for the operation execution. This reduces the number of control bytes by at least half compared to connecting a controller with da.tv code ASCII · The same applies to data transmission in both directions to reduce the number of bytes to 2 versus 5 · The connection of the controller according to the invention further allows:

- programmatically set operations with either 16-bit or 8-bit data · This will double the bit rate for 8-bit data,

- automatically reprocess selected number of channels without sending a new address for measuring analog signals and for data input or output,

- automatic change of measurement time for different ranges of analog input signal, which is proportional to stabilization time of input amplifier ·

The attached drawing schematically illustrates the principle of the JSP controller according to the invention. The controller according to the figure consists of interface circuits 1 whose first IC interface inputs are connected to the IMS-2 interface, their second ID inputs are connected to the first, status outputs 130 of the environmental interface unit 13, the third input 16 to the first control output 61 of the circuit. 6 control of data output and first input 55 of circuits 5 of start of operation, fourth input 18 8 with second control output 13A of the environmental interface unit 13, with first input 116 of circuits 11 2, subaddresses and with first input 105 of circuits 10 1st subaddress, fifth input 19 s the output 73 of the analog-to-digital converter start circuit 7 and the first input 13C of the environmental interface unit 13, the sixth inputs 1A DO 1 to DO 8 with the data output 122 of the data output circuits 12 and the seventh input 1B with the first output 92 of the address the second inlet 133 of the environmental contact unit 13 and the first inlet 71 of the circuit

- 4 -

224,802 analog-to-digital converter start-up waters 7, their first data outputs IE DI 1 to DI 8 being connected to the first inputs 21 of the binary code decoder 2, to the first inputs 84 of the input data memory 8, to the first input 93 of the addressing circuits 9; with the second inputs 107 of the 1st subaddress circuits 10 and with the second inputs 118 of the 2nd subaddress circuits 11, their second control output 14 being connected to the second input 20 of the binary code decoder i.2, the third control output 15 with the first input 44 of the control circuits 4 the first recording output 22 of the binary code decoder 2 is connected to the second input 94 of the addressing circuit 9, the second, the recording output 23 to the third input 106 of the sub-address circuits 10h, the third recording output 24 with the third input 117 of the circuits 11 of the second subaddress, the fourth control output 25 with the first input 31 of the single-byte control circuit 3 5, control output 26 with second input 32 of single-mode control circuits 3, sixth, control output 28 with second input 45 of data input control circuits 4, seventh, control output 29 with second input 57 of operation start circuits 5 and third input 27 is coupled to the first, blocking output 41 of the data input control circuits 4. The output 33 of the single-byte mode control circuit 3 is connected to the third input 46 of the data input control circuits 4, to the third input 58 of the operation start circuits 5 and to the second input 66 of the data output control circuits 6 while the second control output 42

1, the byte circuit 4 of the data input control is coupled to the fourth input 104 of the circuits 10 1 of the subaddress, to the fourth input 111 of the circuits 11 of the second subaddress, to the second input 83 of the input data memory 8 and to the fourth input 52 control output 43

The 2nd byte is coupled to the fifth input 103 of the 10 < 1 > subaddresses, the fifth input 112 of the second subaddress 11, the third input 83 of the input data memory 8 and the fifth input 51 of the operation start 5 circuits; is coupled to the third external start output 139 of the environmental contact unit 13, the seventh input 54 with the second control output 62 transmitting 2 byte of the data output control circuit 6, and the first input 123 of the data output circuit 12 and its output 56 connected to the third input 65 the data input control circuits 6, with the tenth input 13D of the environmental contact unit 13, and the second input 74 of the analog-to-digital converter start circuits 7. The third inputs 72 of the analog-to-digital converter start circuits 7 are coupled to the first outputs 102 of the 10 1 subaddress ranges and to the third inputs 135 units.

- 5 224 802 ky 13 environment, while the sixth input 108 circuits 10 1 · subaddress is connected to the fourth control output 119 circuits 11 ‘

2. the subaddresses and second channel address outputs 101 are connected to the fourth inputs 134 of the environmental contact unit 13, the fifth inputs 131 of which are connected to the outputs 81 of input data B1 0 to B1 15 of the input data memory 8, the sixth inputs 132 to the second the outputs 91 of the addressing circuits 9, the seventh inputs 136 β by the first outputs 113 of the circuit functions 11 2, the subaddresses, the eighth input 137 with the second output 114 of the sub-address circuitry 11 sampling and the ninth input 138 with the third output 115 of the circuit board the fourth output data outputs 13B BO 0 to BO 15 are coupled to the second inputs 121 of the data output circuits 12, the third input 124 of which is connected to the third, control output 63 of transmitting 1 '

The operation of the JSP controller according to the invention consists in that the JSP is controlled by the IMS-2 interface via the circuitry 1 by a maximum of four single-byte control words from 1 · data output IE with signals 01 1 to D1 8 circuitry 1 Binary code from bits D16 to D17 • The first control word determines the board address given by bits D11 to D15 and the address of the analog-to-digital converter given by bit D18 which can be selected at the same time as the board address. Address recording performs the first recording output 22 of the binary code decoder 2 to the addressing circuits 9. The second control word determines the 1st subaddress by which the second recording output 23 records the channel address of bits D1 to D14 and bits D1 and D1 to bits 10 1st subaddress. The third control word determines 2, the subaddress with which the third recording output 24 records the number of channels of bits D1 1 to D1 4 and the function of bits D1 5 and D18 to the circuits 11 of the 2nd subaddress. · subaddress generates channel control control signals at second channel sampling output 114 and board sampling control signal at third board sampling output 115 · fourth control word sends commands specified by bits D11 to The single-byte mode setting command is provided from the fourth control output 25 of the binary code decoder 2 and the double-byte mode setting command from the fifth control output 26 to the 1-byte mode control circuit 3 whose output 33 sets the single-byte mode in the respective circuits. Further, the sixth, control output 28 gives a command for setting— 6 -

224 802 data input mode to JSP 13 in data input control circuit 4 which is canceled by a signal from the third, control output 15 of the interface circuits 1 · The start command is transmitted from the seventh, control output 29 of the binary code decoder 2 and further processed in operation start circuit 5 along with other signals · The strobe signal for control word recording is applied to the second input 20 of the binary code decoder 2 ·

From the addressing circuitry 5, five address signals are input to the JSP 13 internal inputs to the sixth inputs JSP 13 and the analog-to-digital converter address signal to the second input 133,

From circuit 10 1, subaddress 4, channel address signals to fourth inputs 134 of JSP 13, and 4 decoded range signals to third inputs 135. From circuit 11 of second subaddress, 2 function signals are input to JSP 13 bus to seventh inputs 136, one channel sampling signal to the eighth input 137 and one board sampling signal to the ninth input 138 JSP 13.

In automatic multi-channel processing, both when measuring analog signals and recording data in single-byte and double-byte modes, the channel address is incremented by 1 up to the number of channels selected by the 2 · subaddress after the corresponding operation. Then the channel address selected by 1 · subaddress is set again. The channel address is increased by 1 when measuring analog signals by the analog-to-digital converter conversion time signal from the sixth input 105 of the 10 1 · subaddress, when recording input data in single-byte mode 1, data byte 01 1 to DI 8 from fourth input 104 and in the 2-byte mode with signal for recording 2, byte of data D1 1 to DI 8 from fifth input 103, Setting the channel start address is done by signal from sixth input 108 at the end of the selected number of channels. The start of the operation in JSP 13 is performed by the signal from the tenth input 13D and the start of the analog-to-digital converter by the signal from the first input 13C, which is derived from the signal at the input 13D. the inputs 72 of the analog-to-digital converter start circuits 7 and cause the analog-to-digital converter start delay to change automatically with respect to the channel switching time. This delay then corresponds to the stabilization time of the input amplifier at the selected range (gain). The analog-to-digital converter start signal is output at 73 of the analog-to-digital converter start circuits 7 only at the selected address and 7 224 802 of the log-to-digital converter connected to their first input 7l. The operation start signal is generated at the output 56 of the operation start 5 circuits from the following signals at the inputs of the indicated circuits:

- a command to start the operation applied to the second input 57

- from a signal for recording the 2nd byte of input data DI 1 to DI 8 in the two-byte mode applied to the fifth input 51

- a signal for recording 1 »byte of input data DI 1 to DI 8 in single-byte mode applied to the fourth input 52

- from the end of transmission signal 2 · byte of output data DO 1 to DO 8 in two-byte mode, applied to the first input 55

- from the signal of the end of transmission of the 1st byte of output data DO 1 to DO 8 in single-byte mode, applied to the seventh input 54

- and an external start signal applied to the sixth input 53,

When measuring one or more analog signal channels automatically, the next start of the A / D converter is performed automatically after the transmission of 2 bytes of measured data on the IMS-2 bus in two-byte or 1st byte in single-byte mode. recording in JSP 13 automatically by the start signal of the operation from the tenth input 13D derived from the signal for recording the 1st byte of data in single-byte or 2 «byte da.t in two-byte mode ·

After setting the data input mode to the JSP 13 by applying a control signal to the second input 45 of the data input control circuits 4, this circuit transmits a blocking signal to the third input 27 of the binary code decoder 2 to block its operation. byte and third, control output 43 2 · byte · All signals on the first, data output 1E of interface 1 are interpreted as data · Every 2 bytes of data are sequentially recorded to memory circuits 9 and transmitted as 16-byte word BI 0 to BI 15 to the fifth inputs 131 of the JSP 13 bus »

To control the output of 16-bit data BO 0 to BO 15 from JSP 13 on the IMS-2 bus, the data output circuits 12 are used to transmit the first byte signal 1 byte to the third input 124 and the second byte signal 2 DO 1 up to DO 8 for circuit boards 1 «

To control the data output on the IMS-2 bus, readiness status signals of the unaddressed JSP 13 board are used for data transmission and for the second ID inputs, the end of transmission signal 2 · byte of output data - 8 «

224 802

DO 1 to DO 8 at third inputs 16, analog-to-digital converter conversion time signal at fourth input 18. analog-to-digital converter start signal at fifth input 19, and analog-to-digital converter address signal at seventh input 1B of contactor circuits 1.

The connection of the controller to the environmental interface of the present invention takes advantage of all the advantages of being connected to the IMS-2 instrument interface, yet at the same time characterized by a high rate of information transmission and the processing of input and output signals. Its advantages can be used mainly in the field of automation of measurement and control of laboratory work, in testing and development laboratories.

Claims (1)

Pre Μ ET _inventions Controller for a drive contact with the environment, consisting of the interface circuit, the first interface inputs "are connected to the interface IMS-2 _f, characterized in that their second inputs (ID) are connected to the first, status outputs (130) of the unit (13) contacting with the environment, a third input (16) with a first control output (61) of the data output control circuit (6) and a first input (55) of the operation start circuit (5), a fourth input (18) with a second control output (13A) 13) contact with the environment, with the first input (116) of the circuits (11) 2 · subaddresses and with the first input (105) of the circuits (10) 1 * subaddresses, the fifth input (19) with the output (73) of the circuits (7) a digital converter having a first input (13C) of the environmental interface unit (13), a sixth input (1A) DO 1 to DO 8 with a data output (122) of the data output circuits (12), and a seventh input (1B) with a first output (92) ) address of the analog-to-digital converter of addressing circuits (9), s kind - an input (133) of the environmental interface unit (13) and a first input (71) of the analog-to-digital converter start circuits (7), their first, data outputs (IE) DI 1 to DI 8 being connected to the first inputs (21) a binary code decoder (2), with the first inputs (84) of the input data memory (8), the first input (93) of the addressing circuit (9), the second inputs (107) of the circuit (10) 1 subaddress and the second inputs (118) 2) subaddress circuits (11), their second control output (14) being connected to the second input (20) of the binary code decoder (2), the third control output (15) to the first input (44) of the control circuits (4) data inputs and a fourth control output (17) with a first input (64) of data output control circuits (6), while a first, record output (22) of the binary code decoder (2) is coupled to a second input (94) of addressing circuits (9) ), second, recording output (23) with a third input (106) of circuits (10) 1, subaddress, third, recording výstup output (24) with third input (117) of circuits (11) of the 2nd subaddress, fourth, control output (25) with first input (31) of single-mode control circuit (3), fifth, control output (26) with second input (32) single-byte mode control circuitry, sixth, control output (28) with second input (45) circuitry (4) data input control, seventh, control output (29) with second input (57) start circuit (5) operation, the third input (27) being coupled to the first, blocking output (41) of the data input control circuits (4), wherein the output (33) of the single-byte mode control circuits (3) is coupled to the third input (46) of the control circuits (4) inputs 224,802 data, with a third input (58) of the operation start circuit (5) and a second input (66) of the data output control circuit (6), while a second, control output (42) of the 1st byte of the data input control circuit (4) is connected a fourth input (104) of circuits (10) L _e subaddress, a fourth input (111) of circuits (11) of the second sub-address to the second input (82) of memory (8) data input and a fourth input (52) of the circuits (5 ) start of operation and third, control output (43) of the 2nd byte is connected to the fifth input (103) of the circuits (10) of the 1st subaddress, with the fifth input (112) of the circuits (11) of the 2 subaddresses, with the third input (83) an input data memory (8) and a fifth input (51) of the operation start circuit (5), wherein the sixth input (53) of the operation start circuit (5) is connected to a third external start output (139) of the environment contact unit (13); a seventh input (54) with a second control output (62) sending a 2 · byte of the data output control circuit (6) and a first input (123) of the data output circuits (12) and their output (56) is coupled to a third input (65) of the data output control circuits (6), a tenth input (13D) of the environmental interface unit (13), and a second input (74) of the analog-to-digital converter start circuit (71). wherein the third inputs (72) of the analog-to-digital converter start circuits (7) are coupled to the first outputs (102) of the 1st subaddress circuit (10) ranges and to the third inputs (135) of the environmental interface unit (13), ) the 1st subaddress circuitry (10) is coupled to a fourth control output (119) of subaddress circuitry (11) and the second channel address outputs (101) are coupled to the fourth inputs (134) of the environmental contact unit (13), the fifth inputs (131) being connected to the input data outputs (81) B1 0 to B1 15 of the input data memory (8), the sixth inputs (132) with the second address outputs (91) of the addressing circuits (9), the seventh inputs (136) ) with first outputs (113) of functions of the circuits (11) of the 2nd subaddress, eighth an input (137) with a second channel sampling output (114) and a ninth input (138) with a third output (115) of the circuit board sampling (11) 2. subaddresses and fourth outputs (13B) of output data BO 0 to BO 15 are connected to inputs (121) of data output circuits (12), the third input (124) of which is connected to the third control output (63) of transmitting the first byte of the data output control circuits (6).