SU845276A1 - Pulse discriminator - Google Patents

Description

The invention relates to a pulse technique and spectrometry and can be used in pulse analyzers, amplitude meters of statistically distributed sequences of 5 pulses.

A device for rejection of superimposed pulses is known, based on a comparison of the time interval corresponding to the intersection of the zero level with a bipolar signal with a certain fixed time interval of £ 1]. This device provides notch only for pulses with certain parameters, due to the 15th value of a fixed time interval. When changing the parameters of the £ pulse, large errors are possible associated with the loss of undistorted pulses or with the registration of 20 distorted pulses.

The closest in technical essence is the superimposed notch device and the beginning of the impulse containing the imaging marker and the And elements, based on the formation of the time interval beginning - the top of the measured impulse and comparing these intervals G2]. Pulse rejection2 occurs if the duration of the interval beginning - the top of the measured pulse exceeds the duration of the fixed interval.

In this device, large errors are also possible associated with the hard setting of the duration of the generated time interval, leading to a decrease in the accuracy of measurements.

The aim of the invention is to improve the accuracy of measurement.

This is achieved by the fact that in the pulse discriminator containing the elements AND and the driver of the mark the beginning of the pulse, the output of which is connected to the first input of the element And, the driver of the time stamp, the element of NOT, the driver of the control signal, the differentiating element, the trigger, the element OR moreover, the first input of the second element And is connected to the output of the driver of the time from the 25 mark the beginning of the pulse, and the second inputs of the first and second elements And are connected respectively to the zero and unit outputs ode to the trigger, the first input of the third element And connected to QQ through the pulse generator, the top of the pulse, with the input ♦ of the time stamp of the beginning of the pulse, the second input of the third element And connected to the zero output of the trigger, the output of the third element And through series-connected driver of the control signal and differentiating element , and its output is connected to the first input of the OR element, the second input of which is connected to the output of the first AND element, the third input of which is connected through the inverter to the input of the differential at the same time, the outputs of the OR element and the second AND element are connected respectively to the inputs of the trigger.

In FIG. 1 shows a functional diagram of a device; in FIG. 2 is a pulse diagram of the operation of the device.

The device comprises a driver 1 of the time stamp of the beginning of the pulse, driver 2 of the time stamp of the top of the pulse ¹ ', driver 3 of the control signal, elements 4, 5 and 6, element NOT 7, element OR 8, differentiating element 9, trigger 10, key 11, input the bus 12 and the output bus 13 and 14. At the time the measured pulse arrives at the input of the amplifier path, a time stamp is formed (Fig. 2, b). In the amplification path, the input pulse is given the optimal, in terms of signal-to-noise ratio, shape and duration. When the pulse reaches its maximum value, a time mark is formed to achieve Vershinin (Fig. 2, c). At time t ₄ (Fig. 2, a),. a signal is undistorted by overlays and, therefore, is subject to registration. At the moment, a signal arrives at which at the moment t _{3 the} next signal is superimposed (the ratio of signal amplitudes in the general case can be any). The resulting signal carries distorted information and should be excluded from registration.

As can be seen from FIG. 2 in the interval · (the beginning of the signal - the peak) the momentum of the beginning of the next signal arrives at the moment. The arrival of this pulse is a sign by which in the proposed device is the rejection of distorted signals.

The device operates as follows ...

For the initial state of trigger 10, we take 1. Then the signal from the output of the former 1 passes the open element And 5 and sets the trigger 10 to 0. At the same time, the elements And 4 and 6 open, the potential from the output Q of trigger 10 locks the key 1'1, the pulse front passes to bus 13. If, following the signal of the moment of arrival of the pulse at the input of the driver 2, a signal of the peak of the pulse is generated, then this signal passes through the open element And 6 and starts the driver 4 of the control signal. The differentiating element 9 selects the trailing edge of the control signal and, via the OR element 8, the trigger 10 is transferred to state 1. After that, the device is ready to receive the next signal. In the case when the second signal arrives at the bus 12 after the first signal of the moment of arrival of the pulse, it passes the open element And 4 and sets the trigger 10 to state 1. At the same time, the key 11 is blocked by the Ibi element.

The control signal is not generated, i.e. both input pulses are rejected. From the shaper 3 through inverter 7, the signal is supplied to the element And 2. This is necessary to block the element And 4 at the time of formation of the control pulse so that during this time interval there is no flip-flop of the trigger signal from the next input pulse.

The proposed device for the rejection of superimposed pulses can significantly increase the accuracy of the amplitude analysis of pulses by eliminating the hard task of the duration of the generated time interval.

Claims (2)

1. Electronic methods of nuclear medicine, Ki, ed. L. Matalina. Atomizdat, 1973, p. 160-161. 2. IEEE Trans on Nuclear Sbiense, Vol. 6-19, 1, 1972, p. 461. fpaz.f tftjt Figg