SU519866A1 - Pulse frequency divider - Google Patents

Description

Cards with the first input of the additionally inserted OR 9 element with N outputs, the second input of the OR 9 element through the second optical delay line 5 is connected to the second output 10 of the storage device 3, the outputs of the OR 9 element are connected to the corresponding inputs of the storage device 3 from the second through ( .V + l) -ft. Drive 3 contains an input transparency 11 connected optically with the first input 2 of drive 3; L optical cells 12 according to the number of bits of the accumulator, the first input 13 of each of the optical cells 12 is connected with the corresponding input of the accumulator, and the second input 14 with the first output 15 of the previous optical cell, except the first, the second input 14 of which is optically connected with the output entrance transparency 11; The L-input element “OR 16” is connected with the inputs to the second outputs 17 of the optical cells 12, and the output to the second output 10 of the storage unit 3, the first output 8 of which is optically connected to the output 15 of the last optical cell. Each optical cell 12 of accumulator 3 contains a banner 18, the input of which is connected to the first input 13 of the optical cell, and the output - to the first input of the modulo two 19 and the first input of the And 20 element, the second inputs of which are connected to the second optical input 14 cells, the output of the element & 20 is optically coupled with the input of the shifter 21, the output of which is connected with the first output 15 of the optical cell, the second output 17 of which is connected with the output of the modulo-two adder 9. The output of the pulse frequency divider is output 8 of the accumulator 3, which is mated with electronic devices optically coupled to the photodetector array 22. The input device 23 is input, the control change frequency division codes matrix 6.

Changing the frequency division codes of matrix 6 can be accomplished by using a cassette memory of banners on photochromic materials or punched tapes and a tape mechanism, or by using well-known electro-optical controlled banners.

Information coding on optical transparencies is binary; the transparent element corresponds to one, the opaque to zero.

Bee transparencies in the divider have the same dimensions of elements, size and arrangement of numbers on the pictures recorded on them, as well as dimensions.

The matrix of frequency division codes 6 is a removable optical transparency with a picture of numbers written on it corresponding to the codes for dividing the pulse frequency of a given light beam (the numbers are written in an additional code).

The luminous flux in the divider maintains coherence along the entire path and always normals to the optical elements.

The transmission of light flux in the device

implemented using mirror systems or optical fibers.

The multiplier 7 iformatstsi, contained in one column, but all columns of numbers

can be realized, for example, with the help of Voloston prisms or optical systems, including their mirrors and prisms.

The shifter 21 performs an optical shift of the input light pattern by 1 bit.

each number and can be implemented using or mirror. In the last (/ Vth) optical cell, the picture shift is carried out at 0 bits. The resulting picture is getting

output 8 is a divider and is a grid of light beam-pulses, each following its own frequency, defined by the division code recorded in the corresponding number of the matrix of codes of codes 6, can be registered, for example, by a matrix of photodetectors 22 or transmitted through optical channels in Other devices.

Optical delay lines 4 and 5 delay the incoming from the output of the drive to

Entrance light pattern before the arrival of the next light pulse from source 1.

The transparency 18 of the accumulator optical cells selects one bit from the light pattern for all numbers, and the number of the selected bit is equal to the number of the optical cell.

The frequency divider works as follows.

Immediately after switching on the pulsed light source, the zero cycle of operation begins — idle. Optical transparency 11 modulates the light pulse in the form of a picture of numbers with units in the younger category for all numbers. In the first cycle of the zero cycle, the light pattern passes only through the adder.

19, the accumulator's primary cell, then unchanged through the elements 16, is delayed by the optical delay line 5 until the next light pulse arrives from source 1 and enters drive 3 through

element 9, together with the light pattern of units in the 1 smallest bit of all the numbers obtained by modulating the second light pulse from source 1 with a transparency 11.

In the second bar and the following occurs

binary addition in the accumulator 3 pictures obtained in the previous measure, with the picture of units in the lower half of all numbers.

In the Lm cycle of the zero cycle, the addition of the picture of units in all bits

of all numbers obtained in () th also, with a picture of one in the lower order and of all numbers, which results in a picture of zeros in all digits of all numbers and a hyphenation pattern at the output of the jV-th optical cell of the accumulator 7 multiplies in all digits of a number and, after delayed by an optical delay line 4, until modulated, the next pulse is modulated by a banner 11 with a matrix of codes

dividing the frequency together with a captina of zeros, fed from output 10 of accumulator 3 through the element OR 9, and arrives at the banners of the 18 optical cells of the accumulator simultaneously with the first pulse of the first operating cycle from source 1.

The work of the pulse frequency divider in the first and subsequent work cycles is similar to its work in zero n, hoop, with the difference that the number of units in different numbers differs due to the code entered at the beginning of the count, and consequently, the discharge of the bit grid occurs in different numbers of the picture at different times, i.e., the picture of transfers at the output of the divider and the moment of entering the codes into the different numbers in the subsequent cycles are determined by the program of the code matrix, which is written to the banner 11.

Changing the frequency grid is carried out by simply replacing the picture of numbers on a banner with another - with the required matrix of frequency codes.

Claims (3)

1. A pulse frequency divider containing a pulsed coherent light source associated with the first drive input, optical delay lines and a frequency division code matrix, with its first input connected to the device input, characterized in that in order to increase reliability and increase the speed of the device , an optical multiplier is entered in it, the input of which is optically connected to the first output of the accumulator, and the output through the first optical delay line and the division code matrix arranged in series Frequency values are optically connected with the first input of the additionally introduced picture element OR with N outputs, the second input of the element OR through the second optical line, the delays are connected with the second output of the accumulator, the outputs of the element OR are connected with the corresponding inputs of the second from the second () th 2. A frequency divider according to claim 1, characterized in that the drive contains an input transparency optically coupled to the first drive input, L optical cells and the number of bits of the drive, the first input each of the optical cells is associated with the corresponding input of the ionizer, and the second input is connected with the first output of the previous optical cell, except for the first one, the second input is optically connected with the output of the input transparency, OR input element associated with the second outputs the optical cells, and the output with the second output of the storage device, the first output of which is optically coupled to the output of the last optical cell. 3. The frequency divider in paragraphs. 1 and 2, characterized in that in it each optical cell of the accumulator contains a transparency, the entrance of which is connected to the first input and the output with the first input of the modulo two adder and the first input of the AND element, the second inputs of which are connected to the second input of the optical cell, the output of the AND element is optically connected to the input a shifter, the output of which is associated with the first output of the optical cell, the second output of which is associated with the output of the modulo-two adder.