SU1173196A1 - Photon counter - Google Patents

Abstract

A PHOTON ACCOUNT DEVICE, containing a photomultiplier tube, a discriminator, fast, counters, a first operative memory device, an adder, a second random access memory and an electronic computer connected in series, a comparison circuit, a synchronization circuit, a parcel counter connected to the control unit, moreover, the input of the comparison circuit is connected to the output of the adder, the synchronization circuit is connected to the inputs of the counter of the number of parcels and the control unit connected to the first and second A storage device, a comparison circuit, and an electronic computer, characterized in that, in order to improve the accuracy of measuring atmospheric parameters at remote locations of the sounding path, a data multiplexer and a third random access memory are additionally inserted in it, the first input of the multiplexer is connected to the output of the second operational storage device, in (L formational output of the count of the number of powders are connected to the second input of the multiplexer, the output of which is connected to the second The input of the adder and the output of the comparison circuit are connected to the control input of the multiplexer and the input of the third random access memory, the output of the latter is connected to the input data bus of the electronic computer and to the input from the control of the first operational memory that helps. with

Description

The invention relates to the optics of the atmosphere and can be used to register weak, including I1 "pulsed light fluxes in physics, spectroscopy, space research, astronomy, etc." The aim of the invention is to improve the accuracy of atmospheric parameters measurement at remote locations of sounding paths. . , FIG. 1 is a block diagram of a device for counting photons; FIG. 2a shows the distribution of the intensity of the photon flux along the sounding path; FIG. 26 is an intermediate picture of the distribution of information in the second and third operational storage devices. The device for counting photons contains a photomultiplier 1, a discriminator 2, fast counters 3, the first random access memory 4, cjT iMaTop 5, the second operative operating device 6, connected in series, the synchronization circuit 7, the counter 8 of the number of pos, the control unit 9, the multiplexer 10, the comparison circuit 11, the third random access memory 12, the electronic computer and the computer 13. The input of the comparison circuit 11 is connected to the external code of the adder 5, the synchronization circuit 7 is connected to the 1 counter of the 8 numbers nocsibOK and control unit 9 connected to the first 4 and second b random access memory, comparison circuit 11 and electronic computer 13, the first input of the multiplexer is connected to the output of the second random access memory 6, the information outputs of the counter 8 number are connected to the second input the multiplexer 10, the output of which is connected to the second input of the adder 5, and the output of the comparison circuit 11 is connected to the control input of the multiplexer 10 and the input of the third random access memory 12,. which is connected to. the input data bus of the electronic computer 13 and to the input of the first random access memory. The device for photon counting works as follows. Accumulated in the cycle of counting in the cells of the first random access memory 4 numbers corresponding to photons recorded in the time intervals of the sounding path are received in the summation cycle to the first input of the adder 5, to the second input of which data obtained in the previous sounding cycles (counting and adding) from the second random access memory 6 from the cell with the same number as the cell number of the first random access memory 4, the multiplexer 10 in the initial state skips data of the adder 5 to a second random access memory 6. In addition result. the accumulator of numbers from the first 4 and second 6 random access memory at the output of adder 5 appears a new number, which is written into the same cell of the second random access memory 6, from which the number was taken for summation. This process is performed for all cells of the first and second random access memory. Thus, in the second random access memory 6, data is accumulated in each of the cells corresponding to the number of time intervals in which photons were counted in the counting cycle 3. The counting-summing cycle repeated several times after the clock pulse arrived from the circuit synchronization 7, leads to the fact that the cells of the second random access memory 6 accumulate information on the number of registered photons to the required preset level. The counting of cycles is performed in the 8-hour countdown dial. If in the next summation cycle, the result of the summation of the corresponding cells of the first 4 and second 6 RAMs reaches a predetermined level that determines the accuracy of the atmosphere parameter of interest in this time interval, the comparison circuit 11 is triggered and switches the multiplexer 10 so that device 6 through the adder 5 records the number from the counter 8, the number of parcels corresponding to the number of sprinkling, at which in a given time interval (in this cell of the second o An operational storage device 6) ensured that a given accumulation level was reached, ensuring the required measurement accuracy. In this case, from the comparison circuit 11 to the first random access memory 4, the output data prohibition signal is sent, therefore the number from the counter 8 the number of parcels is added to zero, from the first random access memory 4, i.e. In the second random access memory 6, the dressing number is recorded. At the same time, the signal (unit level) from the output of the circuit 11 is recorded in the corresponding cell of the third random access memory 12, operating synchronously with the first 4 and second 6 random access memory. Further filling of the data leads to the achievement of a predetermined level; and in the remaining cells of the second random access memory 6, by changing the information in the filling up cells. This eliminates the summation of the newly arriving data from the first operational memory of device 4 with the state of the cells in which the state of the counter is 8 and the number of dressing has already been recorded And which were marked by writing the unit to the third operating memory in parallel. device 12, since the unit from the output of this cell of the third random access memory blocks the output of the first random access memory 4. When this number of dressings from the output of the second random access memory is added to zero from the output of the first random access memory 4, it is written again permanently the same cell of the second operative memory device, t, e. before reading one of the end of the experiment (criteria is a given accumulation level, the number of parcels, the termination requirement by timer or program with the computer electronics, etc.) the data recorded in the second a random access memory 6 is counted in the electronic computer 13, and the state of the third random access memory 12, read in parallel, is an indicator of information from this The second cell of the second random access memory 6. Matching the unit from the third operational memory of the device 12 corresponds to the number in the second operational memory in the cell of the number of sprinkles, at which the specified accumulation level would be reached, the zero reading records the number of photons accumulated up to this time. FIG. , 2 are shown. JL of the photon flux depending on the distance L, a given accumulation level in the second operative memory device N ,, g is the number of the time interval (the memory cell). Further accumulation of information in the cells of the second random access memory 6 ultimately leads to filling all of the random access memory cells with the numbers of the packages at which the given accumulation level was reached in these cells, which makes it possible to rationally use the useful volume of the second random access memory 6, fill it in necessary cases completely and without loss of information. “Thus, the proposed device makes it possible to measure the parameters of the atmosphere with high accuracy along the entire sounding path and to increase the flexibility of the experiment due to the possibility of accumulating the results not only up to a given number of dressings, but also up to a given accumulation level in one or several (all) cells.

- i

Claims (1)

A PHOTON COUNTER DAY DEVICE comprising a photomultiplier, discriminator, fast, counters, a first random access memory, an adder, a second random access memory and an electronic computer connected in series, a comparison circuit, a synchronization circuit, a counter of the number of packages connected to the control unit, the input of the comparison circuit is connected to the output of the adder, the synchronization circuit is connected to the inputs of the counter of the number of parcels and the control unit connected to the first and second with other devices, a comparison circuit and an electronic computer, characterized in that, in order to improve the accuracy of measuring atmospheric parameters at remote sections of the sensing path, a data multiplexer and a third random access memory are additionally introduced into it, while the first input of the multiplexer is connected to the output of the second operational storage device, information outputs_ of the counter of the number of toppings are connected to the second input of the multiplexer, the output of which is connected to the second input of the total pa, and the output of the comparison circuit is connected to the control input of the multiplexer and the input ’of the third random access memory, the output of the latter is connected to the data input bus of the electronic computer and to the control input of the first random access memory. 1173196 2