CS220128B1 - Connection of function keyboard and connection circuits with parallel data transfer to microprocessor - Google Patents

Abstract

Technical problem solved by the invention: Connection of a functional keyboard and circuits that connect the keyboard to a microprocessor of an electronic device, when data is transmitted in parallel. The buttons of the functional keyboard connected to the matrix are connected to the row and column encoders. The data outputs are routed through the gates to the microprocessor data bus. The encoder group signal output is a character and status memory signal. The keyboard address with a control signal from the microprocessor bus opens the gates when reading a character into the microprocessor. Fields where the invention can be used: Computer technology, peripheral devices with microprocessors, NC machines and electronic devices with microprocessors.

Description

(54) Connection of functional keyboard and connection circuits with parallel data transfer to microprocessor

Technical problem solved by the invention: Connection of a functional keypad and circuits that connect the keypad to a microprocessor of an electronic device where data is transmitted in parallel.

Function keypad keys connected to a matrix are connected to row and column encoders. Data outputs are routed through the gates to the microprocessor data bus. The encoder group signal output is the character and status memory signal. The address of the keyboard with the control signal from the microprocessor bus opens the gates to the microprocessor when reading the tag.

Fields where the invention may be utilized: Computer technology, peripheral devices with microprocessors, NC machines and electronic devices with microprocessors.

The invention relates to the connection of a functional keyboard and connection circuits with parallel data transfer to a microprocessor.

Previous keyboard connections have been built with common integrated circuits. The buttons were plugged into a matrix mostly of different numbers of rows and columns. The circuitry contained a decoder connected, for example, to matrix rows, while control and blocking signals were derived from the matrix columns. The connections were quite complex and confusing, especially for a large number of buttons. The expansion of the number of buttons has almost always led to a new connection. The complexity of the connection also gave a high failure rate.

The presently complex keyboard connection eliminates the wiring of a functional keyboard and connection circuits with parallel data transfer to the microprocessor according to the invention, which is based on the fact that the button matrix is connected with its row outputs to row encoder data inputs and column outputs to column encoder data inputs. both the button matrix and the encoders form the functional keyboard circuits connected by cable to the connecting circuits through which the keyboard is connected to the microprocessor bus, where the line encoder outputs and the column encoder outputs are connected to the character memory data inputs and the encoder group signal output is connected to input the state memory and at the same time the delay circuit to the clock input of the character memory, the address wires from the microprocessor bus being connected to the inputs of the address decoder, which decodes the data address and the state address, the data address it is connected via a multi-function circuit to the character input and status memory reset inputs and second data gate inputs to which the first character outputs are connected, the state address is connected to the second state gate input, the first input of which is the state memory output , the data gate and state gate outputs are connected to the microprocessor bus data wires, wherein the bus control signal is connected to the address input decoder opening input and the response circuit input, the output of which is connected to the bus response signal wire.

The possibility of active connection of the functional keyboard to the microprocessor is realized in such a way that the connection is supplemented by an interrupt request circuit, which is connected to the status memory output and the circuit output is connected to the bus interrupt request wire. The interrupt request enable signal wire is connected to the feedback circuit input and at the same time to the interrupt request circuit reset input and the feedback circuit output is connected to the bus interrupt signal signal wire.

The connection with the extended number of keys of the function keypad is done so that the buttons are divided into matrices, where the outputs of each matrix are connected to their row encoders and column encoders in a known way, while the data outputs of row encoders are connected in parallel and connected to character memory inputs , the outputs of the column encoders are connected in parallel and connected to the inputs of the character memory, the outputs for the group encoder group signal are connected to the inputs of the sum gate whose output is connected to the data input of the character memory, and likewise, the outputs are connected to the summation gate inputs, the output of which is connected to the data input of the character memory, the outputs for the row encoder group signal are connected to the summation gate inputs, the output of which is connected to the state memory input and via the delay circuit n and the clock memory input of the character memory, and finally, the column encoder selection outputs are coupled to the summation gate inputs, the output is connected to the first gate inputs, the output is connected to the second gate inputs, the output is connected to the third gate inputs, and the output is connected to the first a gate input, a second gate input, and a third gate input, wherein the gate output is connected to the encoder selection input, and the gate output is connected to the select input, the gate output to the select input, and the gate output to the select input.

Said connection of a functional keyboard with parallel data transmission and both passive and active connection to the microprocessor and with the possibility of expanding the number of buttons is considerably simpler than the known connections. Simplicity leads to higher reliability, saving of material and lower demands on production and service.

The connection of the functional keyboard and the connection circuits to the microprocessor is shown in the drawings where; Fig. 1 shows the basic wiring of a functional keypad and passive microprocessor access circuits, and the dashed active microprocessor access circuits; Fig. 2 shows the wiring of a functional keyboard with an extended number of buttons.

In the basic wiring of the functional keyboard of FIG. 1, the buttons are connected to a square matrix 4 with a maximum of 64 buttons. The outputs 401 to 408 of the row 4 matrix are connected to the data inputs of the encoder 5 rows, and the outputs 411 to 418 of the columns matrix 4 are connected to the data inputs of the encoder 6 columns. The data outputs 51-53 and B1-63 of the encoders 5 and 6 are routed from the keyboard 1 via a cable 101 to the connecting circuits 2. They are connected to the inputs 711 to 716 of the character memory 7. The output 54, which is a group signal from the encoder 5, is connected to the input 81 of the state memory 8 and via the delay circuit 9 to the clock input of the character memory 7. The address wires 311 to 31n of the microprocessor header 3 are connected to the inputs of the address decoder 11. The data address output 110 is connected via the monostable circuit 12 to the reset inputs of the character memory 7 and the status memory 8. Simultaneously, data 10 is connected to the second gate inputs. The state address 111 is coupled to the second input of the state gate 13. At the first inputs of the data gate 10 are connected the outputs of the character memory 7, and at the first input of the state gate 13 the state memory output 8. The outputs of the data gates 10 and the state gates 13 are connected to the data wires 321 to 32n of the microprocessor bus 3. The bus conductor 33, which is the control signal, is connected to the opening input of the address decoder 11 and to the input of the response circuit 14. The output of the circuit 14 is connected to a conductor 34 which is a bus response signal 3.

The function of this connection is as follows.

When any function key 1 is pressed, one of the output 401 to 408 rows and one of the output 411 to 418 columns is activated at the same time. The encoders 5 and 6 convert the input one of eight to a binary number on outputs 51 to 53 and B1 to 63. This number determines the code of the button pressed. The encoder operates with the priority assigned to the highest input. Thus, when pressing multiple buttons at the same time, only the one button most connected is evaluated. Output 54 the group signal from the encoder is activated whenever one of the inputs is activated. This signal is used after the appropriate delay as a clock for the character memory 7. The state that a character has been loaded into topic 7 is stored in the state memory 8. The microprocessor according to its program first asks if the keyboard has a character ready. It sends a keyboard status address to bus 3, the decoder 11 converts it as a status address 111. For the duration of the control signal 33, the state gate 13 is open, and the microprocessor reads the state of the keyboard. The keyboard character is read in such a way that the microprocessor sends a keyboard data address to bus 3, the decoder 11 converts it as a data address 110 and the data gate 10 is open for the duration of the control signal 33, and the microprocessor reads the keyboard character. At the end of the reading of the data, the monostable circuit transmits a short pulse, thereby clearing both the status memory 8 and the character memory 7. From the control signal 33, the response circuit 14 sends a response signal 34 to which the microprocessor responds by terminating the action. The connection circuits 2 are again able to assume a new keyboard feature

1. The described connection of the keyboard to the microprocessor is so called passive access, because it depends on the program, when the microprocessor takes the character from the keyboard.

Basic connection of functional keyboard 1 resp. the interconnection circuit 15 can be supplemented by an interrupt request circuit 15, which is connected via its input to the output of the state memory 8. The output of circuit 15 is connected to conductor 35 of bus 3, which is an interrupt request. The wiring is further complemented by a feedback circuit 16, which is connected via its input to the bus interruption enable wire 3. The reset input of the circuit 15 is also connected to this wire. The output of the circuit 16 is connected to the wire 37 3.

The function of these circuits is as follows.

By pressing the keypad button 1, the status memory 8 is loaded, thereby activating the circuit 15 which transmits the interrupt request signal 35. When the microprocessor accepts this request, it sends an interrupt request enable signal 36. To enable this, no interrupt is reset, and circuit 16 sends a paused interrupt signal 37. This tells the microprocessor that the keyboard has a ready-to-use character that it already takes in the usual way.

Since the encoder is an eight-input circuit, 64 keys can be used in the 8X6 matrix in the basic wiring. If a keypad with multiple buttons is required, the basic connection can be expanded most advantageously by plugging the other buttons back into the 8X8 nuts. The wiring of the keyboard 1 is then extended by two encoders per button matrix.

An example of a keypad connection with a maximum of 256 buttons is shown in Fig. 2. The buttons are connected to matrices 4A to 4D, each matrix being connected to its encoders row 5A to 5D and column encoders 6A to 6D in a known manner. The data outputs 51 of all line encoders 5A to 5D are connected in parallel and connected to the respective input 71 of the character memory 7. The outputs 52 and 53 of the encoders 5A to 5D rows and outputs 61, 62 and 63 of the encoders 6A to 6D columns are connected in the same way. Outputs 64 of group encoders 6A to 6D are coupled so that the first output is unused, the second and fourth are connected to the summation gate input 17 and the third and fourth are connected to the summation gate input 18. The character memory 7 in the connecting circuits 2 is expanded by two bits against the basic wiring, and the gate outputs 17 and 18 are connected to these inputs 77 and 78. The encoder outputs 54 of lines 5A to 5D are connected to the inputs of the summing gate 19, the output of which is connected to the state memory 8 and via the delay circuit 9 to the clock input 77 of the character memory 7. Outputs 65 of the column encoders 6A to 6D are connected to the summation gate inputs 20A to 20D as follows: output 63A to the first gate input 20B, 20C and 20D; output B5B to the second gate input 20A, 2DC, and 20D; output 65C to the third gate input 20A, 20B and 20D; output 65D to the first gate entrance 20A, to the second gate entrance 208, and to the third gate entrance 20C. The outputs of these gates are connected as follows: output 20A to inputs 50A and 60A selection of encoders 5 and 6 of button matrix 4A; output 20B to inputs 50B and 60B; exit

20C to 5DC and BBC inputs; and output 20D to inputs 50D and BOD.

The extended keyboard function is as follows.

By pressing any button, the corresponding character is output from 71 to 78. The gate output 19 produces a signal track that determines the writing of a character in the character memory 7 as well as a state where the keyboard has a character ready. By pressing one of the buttons, for example from the matrix 4A, the buttons connected to the other matrices 4B to 4D must be blocked so that the output character cannot be broken. The blocking is provided by appropriately interconnecting the output selections 65 and the inputs 50 and BO selection of the encoders 5 and 6.

The above described wiring of the function keypad and connection circuits can be varied in various ways. For example, swap the outputs 54 of the row encoders with the outputs 64 of the column encoders and vice versa. Similarly, outputs B5 and 55. Depending on the microprocessor used, the address decoder 11 can be changed or omitted. Furthermore, it is possible to modify the bus signals 3, for example by inserting power drivers, inverters or the like. In the same way, it is possible to adjust the keyboard outputs 1 according to the length of the cable 101, the memory used 7 and 8 by inserting power drivers, inverters or terminators.

Claims (3)

SUBJECT 1. Connection of a functional keyboard and connection circuits with parallel data transfer to a microprocessor, characterized in that the button matrix (4) with its outputs (401 to 408) is connected to the data inputs of the encoder (5) of the row, and its outputs (411 to 418) columns connected to the data inputs of the column encoder (6), whereby both the button matrix (4) and the encoders (5, 6) form circuits of the functional keyboard (1) connected by a cable (101) to the connecting circuits (2) through a keyboard (1) connected to the microprocessor bus (3), wherein the outputs (51 to 53) of the encoder (5) row and outputs (61 to 63) of the column encoder (6) are connected to data inputs (71 to 76) of memory (7) and the output (54) for the group signal encoder (5) is connected to the input (81) of the state memory (8) and simultaneously via the delay circuit (9) to the clock input of the character memory (7), the address wires (311 to 31n). the bus (3) of the microprocessor are connected the address of the data decoder (11), which decodes the data address (110) and the state address (111), the data address (110) being connected via a monostable circuit (12) to the reset inputs of the character memory (7) and memory (8) state and further to the second data gate inputs (10), to which the first memory inputs (7) of the character memory (7) are connected, the state address (111) is connected to the second state gate (13), 8) the state, the outputs of the data gates (10) and the state gates (13) are connected to the data wires (321-32n) of the microprocessor bus (3), the control signal (33) from the bus (3) being connected to the opening input of the decoder ( 11) addresses and input of response circuits (14), the output of which is connected to a bus (1314) of the bus response signal (3). 2. Circuit functional keyboard according to claim 1, characterized in that the circuit is completed (15) a request for interrupt ^1, which is its input connected to the output memory (8) state, while the output of the circumference (15) is bonded on the wire přiynAlezu (35) bus interrupt request (3), further completed by a feedback circuit (16), wherein the interrupt request enable signal wire (36) is connected to the input of the feedback circuit (16) and simultaneously to the reset input of the circuit (16); 15) an interrupt request, and the output of the feedback circuit (16) is connected to a wire (37) for the bus interrupt signal (3). 3. Function keypad connection according to items 1 and 2, characterized in that the buttons are divided into matrices (4A to 4D), where the outputs of each matrix are connected to their row encoders (5A to 5D) and column encoders (6A to 6D) In a known manner, the data outputs (51A to 51D) of the row encoders 5A to 5D) are connected in parallel and connected to the inputs (71) of the character memory (7), the outputs (52A to 52D and 53A to 53D) are connected. (72 to 73) as well as data outputs (B11A to 6I1D, 6'2A to 612D and 63A to 630) of the column encoders (6A to 6D) are connected in parallel and connected to the inputs (74 to 76) of the character memory (7) further, the outputs (64B and 64D) for the group encoders (6B and 6D) of the columns are connected to the inputs of the summation gate (17), the output of which is connected to the data input (77) of the character memory (7). 64D) are connected to the inputs of the summation gate (18) whose output connected to the data input (78) of the character memory (7), the outputs (54A to 54D) for the group signal encoders (5A to 5D) of the row are connected to the inputs of the summation gate (19) whose output is connected to the memory input (81) (8) the state and through the delay circuit (9) to the clock input of the character memory (7) and finally the outputs (65A to 65D) for selecting the column encoders (6A to 6D) are coupled to the summation gate inputs (20A to 20D); (65A) is connected to the first gate inputs (20B, 20C and 20D), the output (65B) is connected to the second gate inputs (20A, 20C and 20D), 22012 »the output (65C) is connected to the third gate inputs (20A, 20B, 20D) and the output (65D) is connected to the first gate input (20A), the second gate input (20B), and the third gate input (20C), wherein the gate output (20A) is connected to the input (50A and 60A) to select the encoders [5A and 6A] and the gate output (20B) is connected to the input (50B and 60B) for selection, the gate output (20C) to the input (50C and 60C) to select and output the gate (20D) to the input (50D and 60D) to select.