SU1015442A1 - Shift register - Google Patents

Abstract

REGISTER SSShIGA, containing two groups of electron-optical memory elements, the first inputs of which are connected to the reset bus, the second input and the first output of a hygdia electronic memory element of the first group. Optically connected to the first output and BTOPEIM input of each electron-optical element memory of the second group, respectively, the control bus and the power bus, characterized in that, in order to expand the scope of the shift register due to the possibility of carrying out the reverse shift of the information, equal light source and keys, the first ones of which are connected to the control bus, second keys inputs are connected respectively to the power buses, controls the input of the controlled light source is the information input of the shift register, the first output of the first key is connected to the first output of the second key and .the third inputs of the electro-optical memory elements the second output of the first key is connected to the second output of the second § key and the fourth inputs of the electronically-portable memory elements (P output of the controlled source Single optically coupled with n inputs tymi first and last electron-optical memory elements of the first and second groups of g, the first output of each electron-optical memory element of the first group is connected to the sixth vhodami.predaduschih electron-optical elements of the first and second groups. tn

Description

The invention relates to computing technology and can be used in digital computing devices, visual display devices, moving text indicators or dynamic display boards. five

A shift register is known, containing optocouplers with photoresistors and positive feedback radiators, as well as additional emitters and two clock memories.

PULS Tl 1 ...,

The disadvantage of the device is the impossibility of using such a register for dynamic boards, since in it two adjacent optocoupler 5s are powered from different buses of clock pulses and cannot simultaneously be in the state of radiation, which is necessary. Dimo for dynamic scoreboards. In addition, the number of image cells - "Or optocrypt can be in such a register only even. The disadvantage is also the presence of two tires of the clock pulse.

A shift register is also known, “-containing two groups of electron-optical memory elements, in which the outputs of the bits corresponding to each other are combined 2.,

The disadvantage of the known device: is that at each time point 30 they contain the same information, which is hardware redundant.

Closest to the proposed by the technical entity is the shift register 35, which contains two groups of electro-optical memory elements, which in each group are connected electrically in series, the setup bus to the initial state, 40 connected to the zero inputs, and the single inputs of the first and second groups, respectively, and the zero input and the unit output of each memory element of the first group are optically connected with the optically single output and the zero input of each memory element of the second group, respectively,

The disadvantage of this shift register is the inability to use. its dynamic display boards for shifting changing information. at the input of the register, since it can operate only as a reversible counter and register with the presentation of information in a single direct 55 and inverse codes. With the help of a known register, it is impossible to obtain the alternation of single and zero states in adjacent memory elements in either the first or second groups of 60 memory elements.

The purpose of the invention is to expand the range of application of the shift register | 3a by allowing for the implementation of a shearsive information shift. gf

The goal is achieved by the fact that in a shift register containing two groups of electro-optical memory elements, the first inputs of which are connected to the reset bus, the second input and the first output of each electro-optical memory element of the first group are optically connected to the first output and the second the input of each electron-optical memory element, the second group, respectively, the control bus and the power bus, a controlled light source and keys, the first inputs of which are connected to the control bus, are entered; the second inputs of the keys are connected enes respectively to power buses, a control input of the controllable light source is a data input of the shift register, the first output. the first key is connected to the primary output of the second key and the third inputs of the optical optical memory elements, the second output of the first switch is connected to the second output of the second key and the quarter inputs of the aileron optical optical memory elements, the output of the controlled light source is optically connected to the fifth inputs of the First and the last electro-optical memory elements of the first and second groups, the first output of each electro-optical memory element of the first group is connected to the sixth inputs of the previous electro-optical elements comrade memory first and second groups. I.

The drawing shows a functional diagram of the proposed shift register.

The register contains a controllable light source 1, keys 2 and 3, electro-optical elements 4 of the memory of the first group, electro-optical elements 5 of the memory of the second group, control bus b, power bus 7 and 8, reset bus 9. The controllable light source 1 contains an element NOT 10, resistors 11 and 12, LEDs 13 and 14.

The device works as follows.

At the initial moment of time, due to the influence of the pulse set on the bus 9, the shift register is set to the initial state, i.e. all of the electron-optical eutements 4 of the memory of the first group are set to the zero state, and all the elements 5 of the memory of the second group are set to one. . When a controlled signal is applied to the control bus B, keys 2 and 3 are included. On the bus-7 and 8 meals, filed. respectively, the voltage of the positive and negative polarities. On the first outputs of the keys 2 and 3

positive voltage appears Let the initial signal at the input of the register be a signal of a logical unit. In other words, the information at the input varies in time with the clock steps as follows 1111 ... In this case, the shift register will operate in the right-shift mode of the input information. When the first logical unit appears at the input of the register, the LED 13 starts to emit and the LED 14 goes out. Due to this, for the first shift cycle the first memory 4 of the first group goes to the single state, the first memory 5 of the second group goes to the zero state, since the signal from the output of the light source 1 is affected; it connects to the fifth inputs of the first elements 4 and 5 of the first and second groups. At .31T at the output of the shift register, there is no optical input signal. The code in the first group of elements 4 will be 1 О О О О ... In the second group of elements 5 there will be an inverse code О 1 1 1 ... In the subsequent shift cycles, the elements 4 of the first group successively go into one state and the corresponding elements of 5 second group. If it is necessary to stop shifting the input information, then a control signal is received from the control bus 6 and the keys 2 and 3 are in the initial state.

When the control signal is supplied to the left on the control bus b, the keys 2 and 3 are turned on again and a positive polarity appears on the second inputs. .

Suppose that the following infogmiytsi is recorded in the shift register: in the first group of elements -4 11,100 ....; in the second group of elements 5 - 00011 ....

There is no input signal on the register in this mode. In this case, the register will operate in shift mode | left input information. In the first shift cycle, the third element 5 of the second group enters the unit state and the third element 4 of the first group is zeroed.

After the first shift stroke, the recorded information in the shift register will be: in the first group of elements 4–11000 .... in the SECOND group of elements 5–00111 ....

In the next two clock cycles, the second and first elements 5 of the second group and elements 4 of the first group go to one state. If it is necessary to stop the shearing process, a control signal is sent from the bit b and the keys 2 and 3 are in the initial state. If it is necessary to shift information to the left by n elements

Items 4 and 5, starting with the most significant bit, must be fed to the input of a register equal to n clock cycles.

Let it be necessary to shift 5 any input information to the right. For example, a logical unit with a duration equal to two shift cycles, and after a time equal to one shift cycle is fed to the input of the register.

In other words, the information at the input of the register varies in time in ticks as follows ilOlll. In this case, when the control signal is sent from bus 6 at the first outputs

5 keys 2 and 3 there is a positive voltage.

When the first logical unit appears at the input of the register 8, the LED 13 starts to emit and goes out, the LED 14. Thank you for this in

0 the first shift stroke of the first 4 goes into one state, and the first memory element 5 is in the zero state .. The code in the first group of elements 4 will be 1000, the code in the second

 the group of elements 5 will be 0111. In the | Second shift cycle, a signal corresponding to the level of the logical unit appears again at the input of the register, and element 4 will remain in the single state, and element 5 will remain in the zero state. As a result of the fact that the signal | C of the optical output of the first elenen. 4 affected the sixth input. the second element 5 and the fifth input

5 of the second element 4, the latter in the second clock cycle will go to one, the state, and the second element 5 will go to the zero state. The code in the cert group of elements 4 after two cycles

0 will look at 11000, and in the second group of elements will be 5 - 00111.

In the third shift cycle, a logical zero appears at the register input and the LED 13 ceases to emit,

f a begins to emit the light 14, since the latter is connected to the output of the element HE 10, the output of which is a logical unit. Due to this optical signal from the output of the light source 1, the first element 4 is set to the zero state, and the first element 5 is set to the single state.

The signal from the optical output of per for55 element 4 will not change the state of the second elements 4 and 5 of the first and second groups. The signal from the optical output of the second element 4 in the third cycle will be set to one. state is the third element 5. and in the zero state is the third element 4; The codes will be accordingly: in the first group - 011000, in the second 10111. In the fourth cycle, the logical unit at the register input is redefined; tset. the first element 4 is in the unit state, and the first element 5 is in the zero state. The information in the first group of elements 4 and in the second group is shifted by one element. The codes will accordingly be as follows: in the first rpynrie of elements 4, 101100, in the second group of elements 5 - 010011. Similarly, the process continued. Suppose that it is necessary to shift the information recorded in the register to the left. Let the following information be recorded in the register: in the first group of elements 4 - 1Ш0111, in the second group of elements 5 - 001000. At the same time, with a control signal from the bus b, the second inputs of keys 2 and 3 appear positive. The codes in elements 4 and 5 will be respectively as follows: in the first group -1011100, in the second group 0100011. Similarly, the process goes on and on. From the operation of the device, it is clear that the first group of elements 4 reproduces optical information in the forward code, and the second group of elements 5 in the inverse code. The proposed shift register can shift any sequence of input information to the right and left, which expands its scope. Like the known register, it can be used to convert time to a single code. If during the measured time the input of the register is affected by: a signal corresponding to the level of the logical unit, then the first group will contain elements 4 of the first group, how many shear cycles will be placed in the changed measured time interval,. in the register there will be a single code corresponding to the measured time interval in the first group and the inverse code in elements 5 in the second group. The shift register can be used in information display devices for dynamic scoreboards, in which both positive and negative images are reproduced in the register, since in the first group of elements the direct code is reproduced, and in the second - the inverse one, and also can be used as reversible counter, sequential adder and time interval into code converter.

Claims (1)

SHIFT REGISTER, containing two groups of electro-optical memory elements, the first inputs of which are connected to the reset bus, the second input and the first output of each electro-optical memory element of the first group. They are optically connected with the first output and second input of each electro-optical memory element of the second group accordingly, a control bus and a power bus, characterized in that, in order to expand the area of application of the shift register due to the possibility of performing a reverse shift of information, control emy light source and the key, the first input being connected to the control bus, the second input keys are respectively connected to power buses, a control input to control the light source is an information input of the shift register, the first output of the first switch is connected to the first output. the second key and the third inputs of the electro-optical memory elements, the second output of the first key is connected to the second output of the second key and the fourth inputs of the electron-optical memory elements, the output of the controlled light source is connected optically to the fifth inputs of the first and last electron-optical elements memory of the first and second groups, the first output of each electronic-optical memory element of the first group is connected to. sixth inputs of the previous electron-optical elements of the first and second groups. ™ SU, „. 1015442