SU1277952A1 - Scanning device - Google Patents

Abstract

The invention relates to radioisotope scanning equipment with compensation for time delays and improves the accuracy of compensation for time delays by making the time delays compensation block electronic. The device comprises an actuator, a boom and a detecting unit associated with the recording unit through a conversion system, and a time delay compensation unit. including a random access memory 6 with memory cells, an adder 7, a reversible counter 8, a logic device 9 and a generator 10. The number of memory cells of device 6 is selected based on the maximum line length and resolution. The frequency of oscillator 10 changes as the scanning speed changes. When moving along the line to the right, information about it is recorded in the device 6 not from the first cell, but from the cell, determined by a delay equal to the constant time. The next line moves to the left, (About the time at which the input of the adder 7 generates a code, the reading of which (L provides for the subsequent delay along the same line to the right to compensate for the time delay of the previous line. 3 Il.

Description

1 1 The invention relates to medical technology, namely to radioisotope scanning equipment with BpeijieHHbix delay compensation. The purpose of the invention is to increase the accuracy of time delay compensation. The goal is achieved by making the time delay compensation module electronically. FIG. 1 shows a scanning device, general view; in fig. 2 block compensation time delays; in fig. 3 -. The diagram of the work block compensation time delays. The scanning device contains an actuator, a rod 1, which carries on itself a detection unit 2. and a register 3, the latter being electrically connected to each other after. formatively connected electronic signal conversion system 4 and time delay compensation unit 5. The time delay compensation unit 5 is made electronically and includes a random access memory 6 containing memory cells, the number of which is selected based on the maximum line length and scanner resolution. The address inputs of the operative storage device 6 are connected to the outputs of the adder 7 connected to the outputs of the reversible counter 8 and to the outputs of the logic device 9. The first output of the generator 10 clock pulses is connected to the counting input of the reversing counter 8f and the second output - with the input of the memory of the operative storage device 6. The operation of the time delay compensation unit 5 is synchronized with the same control signals of the drive, with the help of which a control rod 1. The device works sleduyuschkEM of time. Gamma quanta emitted by the patient's examined body are recorded with a detecting unit 2, making reciprocating movements, and, as a sequence of statically distributed pulses, enter the input of an electronic signal conversion system. The signal conversion system 4 produces normalizing input 2 pulses in amplitude and duration, measures the average counting rate and encodes it into a digital code, proportional to the radiation activity of the area over which the detecting unit 2 is currently scanning. This code then enters the registration unit 3, where it is decoded either to the appropriate incandescent lamp brightness (when taking photographs), or in the number of strokes (during bar registration), or to the corresponding color (with multicolor registration). But since the digital code at the output of the electronic signal conversion system 4 appears with a time delay determined mainly by the time constant of the counting rate meter, this leads to delays in the start of registration relative to the beginning of movement of the detection unit 2, which in turn leads to displacement of two adjacent lines of the image on the carrier relative to each other by an amount equal to twice the product of the value of the scanning speed V by the value of a constant time t, which causes distortion of the image and. To eliminate these distortions, time delay compensation unit 5 is used. At the beginning of the scanning process, depending on the expected flux of ionizing radiation, the operator selects the scanning speed V and the time constant of the count rate meter. Logic unit 9 converts the values of these quantities into a binary code of the decimal number K-1, where K is the number of pulses generated by the generator of 10 clock pulses with a frequency f in a time equal to a constant time, i.e. To t-f, whence K: / f. The scan starts by moving the detection unit 2 along the line, for example, Right. At the same time, a synchronizing signal is sent from the drive, which triggers a clock pulse generator 10, which begins to produce read and write pulses in such a way that from the cell of interest to the random access memory 6, information is read first, then write

31277952

new, and on the trailing edge of the write pulse, the address of the cells changes.

To record information from the output of the electronic conversion system 4, the memory cells are allocated from the first to the end (where m p) of the random access memory 6 included in block 5 of compensation for the time delays. The address of the memory cells is determined only by the contents of the binary reversing counter 8, the up-to-date count is the summation of pulses of the clock generator 10, since the outputs of the logic device 9 contain zeros. The number of memory cells per rear line length remains constant at different motion speeds, as when changing the scanning speed, the frequency of the speed generator 10 automatically changes. The frequency f of the generator 10 clock pulses at a given scan speed is selected based on the resolution of the scanner. After the cessation of movement along the line Forward, all information about it in the form of a binary code is recorded in the random access memory 6, but with a delay equal to the constant time. Consequently, the information of interest is not recorded from the first cell, but from (K + 1) -th, since G K / f. Next, detection unit 2 steps over to the second line and starts moving to the Left. At the same time, the drive clock signals transfer the reversible counter 8 to the counting - subtraction mode and allow the logic device 9 to load the binary code of the K-1 number to the input of the adder 7. Now, to record the information coming from the output of the signal conversion system 4 storage device 6, starting with (t + 1) + (K-1) (w + K) -th and ending K + 1. During the movement along the second line, the numerical code is also combined and recorded on the carrier of the first line, starting from its end, but with a delay equal to the time to read the additional cells, i.e. t (ay -) - jn K / f, but K / f.

In this way, the time delay of the first row is compensated.

Claims (1)

Upon termination of movement on the second line, information about it is recorded in the operational memory 6, but with a delay equal to the constant time b and, therefore, the information of interest is recorded not from the (11H-K) th cell, but from (t + K) -K to-oh, while the information on the first line is registered on the media. Next, detection unit 2 steps over to the third line and moves to the right. In this case, the drive clock signals transfer the reversible counter 8 to the counting-summing mode, prohibit the logical device 9 from increasing the binary code of the K-1 number, and to start the information coming from the output of the signal conversion system 4, again, the memory cells 6 begin from the first. At the same time, information about the second line is read, but with a delay equal to the time for reading additional cells: t (K + l) K / f, t.e. the time delay and the second row are compensated. The compensation for the time delays of subsequent lines is similar. Scanning device comprising a drive, a bar, a carrier of a detecting unit and a recording unit, an electronic signal conversion system, the input of which is connected to the output of the detecting unit and a time delay compensation unit, in order to increase the accuracy of compensation of time delays, the block of compensation for time delays contains a random access memory, an adder, a reversible counter, a clock I1 generator, a logic device, and the address inputs are vnogo storage device connected to the outputs of the adder, one input group is connected to Exit dogichesko th device and the torus input group - reersivnogo to the outputs of the counter, the first output n