RU106385U1 - TEST SIGNAL GENERATOR FOR STUDYING THE NONLINEARITY OF VIDEO PULSE SIGNAL CONVERSION BY OBJECT - Google Patents

Abstract

 1. A generator of test signals, including a source of a periodic sequence of short video pulses, characterized in that the output of this source is connected to a delay element, the output of which is connected to the input of the first electronic switch, the first output of which is connected to the first input of the second electronic switch, and the second output of the first electronic the switch is connected to the input of the phase corrector, the output of which is connected to the second input of the second electronic switch, while the output of the second electronic to the mutator is the output of the generator, and the inputs of the switching signal of the electronic switches are connected to the output of the frequency divider by two, the input of which is connected to the output of the source of the periodic sequence of short video pulses, the input of the first electronic switch normally closed with its first output, and the first input of the second electronic switch normally closed with his exit. ! 2. The test signal generator according to claim 1, characterized in that the source of the periodic sequence of short video pulses is made in the form of a binary pulse counter and a logical element AND with the number of inputs equal to the number of binary bits of the counter, and a separate signal is connected to the output of each of the bits of the binary pulse counter the input of the logical element AND, while the output of this logical element is the output of the source of the periodic sequence of short video pulses, and the delay element is executed n as a shift register, the clock inputs of the binary pulse counter and shift register connected to a clock generator and

Description

The utility model relates to the field of radio engineering and is intended to receive test signals by means of which the non-linearity of the conversion of video-pulse signals by an object is studied within the framework of the method described in patent RU 2263929 C1 (priority date 07.04.2004, published 10.11.2005).

A known test signal generator [1], containing an electronic computer that generates test signals in digital form, from the output of which these test signals are fed to a digital-to-analog converter, the output of which is the output of the generator. A disadvantage of the known generator is complexity and high cost.

The closest in technical essence to the claimed device is a generator [2], containing a source of a periodic sequence of short video pulses, the output signal of which is supplied to the object under study, as well as to the first, second and third delay lines, the delay time in which is respectively T, 2T and 3T, and the signal from the output of the second delay line also arrives at the object under study, and the signals from the outputs of the first and third delay lines arrive at the object under study, respectively, through the first and Torah inverters. As a result, pulses with different polarity but identical (accurate to sign) shapes are formed at the output of the generator. The disadvantage of this prototype device is that such a signal is unsuitable for studying the nonlinearity of signal conversion by objects for which S [-x (t)] = - S [x (t)], where S (•) is a non-linear operator that transforms the test impact on the object x (t) in the response of the object: u (t) = S [x (t)]. Such objects include, in particular, inertialess objects whose current-voltage characteristic is an odd function, as well as metal-oxide-metal contacts.

The technical result, the achievement of which the proposed solution is directed, is to create a simple generator of a periodic signal in which pairs of pulses are repeated, and the pulses forming a pair have different shapes.

This is achieved by the fact that in the known test signal generator containing a source of a periodic sequence of short video pulses, the first electronic switch is further included, the input of which is connected through a delay element to the output of the video pulse source, the first output of the first electronic switch connected to the first input of the second electronic switch, and the second output of the first electronic switch is connected to the input of the phase corrector, the output of which is connected to the second input of the second ele ctron switch, while the output of the second electronic switch is the output of the generator, and the inputs of the switching signal of the electronic switches are connected to the output of the frequency divider by two, the input of which is connected to the output of the source of the periodic sequence of short video pulses, and the input of the first electronic switch is normally closed with its first output, and the first input of the second electronic switch is normally closed with its output.

In a particular case, the source of the periodic sequence of short video pulses is performed in the form of a binary pulse counter and logical element And with the number of inputs equal to the number of binary bits of the counter, and a separate input of the logical element And is connected to the output of each bit of the binary pulse counter, while the output of this the logical element is the output of the source of the periodic sequence of short video pulses, and the delay element is made in the form of a shift register, and the clock The counter and register inputs are connected to a clock.

A phase corrector is used to convert the waveform coming from the source of a periodic sequence of short video pulses. The second electronic switch allows to output either pulses of an unchanged shape (such as they have at the output of a source of a periodic sequence of short video pulses), or pulses converted in shape by a phase corrector. The first electronic switch disconnects the phase corrector from the source of the periodic sequence of short video pulses in the case when the signals are output to the generator without form conversion. This is necessary in order to exclude the influence of the input impedance of the phase corrector on the shape of the pulses in this case. The frequency divider for two controls electronic switches, providing alternation at the output of the pulse generator of an unchanged and transformed shape. The delay element provides a delay of the pulse passing through the electronic switches, relative to the moment of their switching. This is necessary so that the transient processes in electronic switches associated with their switching are completely completed by the time the pulse is fed to their inputs.

As a result, the odd video pulses pass from the source of the video pulses to the generator output without changes, and the even ones pass through the phase corrector, which changes their shape. Thus, a periodic sequence of pairs of pulses is obtained in which the pair-forming pulses have different shapes.

Figure 1 presents the structural diagram of the proposed test signal generator, where AI is the source of the periodic sequence of short video pulses, EZ is the delay element, DA1 and DA2 are the first and second electronic keys, respectively, the PM is a frequency divider by two. Figure 2 shows an example of a circuit diagram that implements the proposed utility model. Figure 3 shows the signal u _o (t) (curve 1) at the output of the generator made according to the scheme of figure 2, as well as the signal u _to (t) (curve 2), which switches electronic switches in this generator.

The following is an example implementation of a utility model.

The source of the periodic sequence of short video pulses is made on the DD2 SN74LS161A microcircuit (Fig. 2), which is a binary pulse counter with the AND element included in its composition, whose inputs are connected to the outputs of the counter bits. On the elements DD1.1 and DD1.2 of the DD1 chip SN74LS00, the resistors R1-R2, the capacitor C1 and the quartz resonator ZQ1, a clock generator with a frequency of f ₀ = 16 MHz is made. The signal from the output of the clock generator is fed to the clock input From the counter DD2. The pulse at the output of the logical element AND (the output of the TC of the chip DD2) of the counter is obtained only when all the bits of the counter are in the state of a logical unit. Thus, a periodic sequence of short video pulses with a duration of 1 / f ₀ with a repetition period of 16 / f ₀ (i.e., the pulse duration is 1/16 of the signal period) is formed at the output of the TS of the DD2 chip. The output of the TC of the DD2 chip is the output of the source of the periodic sequence of short video pulses.

The delay element is made on the shift register DD3 SN74LS194A. Pulses from the source of the periodic sequence of short video pulses are fed to the serial input of the DSR register. To the clock input C register connected to the output of the clock generator. When a clock front arrives at this input, the data stored in the register is shifted to the higher bits and the data is written to the lower bit from the DSR input. As a result, the pulse at the output Q2 of the penultimate discharge of the register (arriving at the input of the first electronic switch) is delayed relative to the pulse at the output of the source of the periodic sequence of short video pulses (switching the trigger of the frequency divider by two, which controls the electronic switches) for three periods of the clock frequency, t. e. at 188 ns. This is enough for the transients in the electronic keys associated with their switching to end.

Electronic switches are made on the DA1 ADG5436BRUZ chip. Switching electronic switches is carried out by a signal from the output of the frequency divider into two, implemented on the DD4 SN74LS74A chip.

The phase corrector is implemented according to the well-known scheme [3] on the elements C2-C3 and L1-L3. The values of the corrector elements are designed for the load resistance of the test signal generator 230 Ohms.

At the output of the test signal generator, the signal shown in Fig. 3 is obtained, which is a periodic sequence of pairs of pulses in which the pair of pulses having different shapes.

Sources of information used in the preparation of the description of the utility model:

1. Bombizov A.A., Ladur A.A., Loshchilov A.G., Malyutin N.D., Misyunas A.O., Semenov E.V., Fateev A.V., Usubaliev N.A. Vector pulse meter of characteristics of circuits and wire systems // Devices. - 2007. - No. 9. - S. 28-31.

2. Avdeev V. B., Berdyshev A. V., Panychev S. N. Ultrashort-pulse ultra-wideband nonlinear radar // Telecommunications. - 2006. - No. 8. - S.23-27 - prototype.

3. Silvinskaya K.A., Golyshko Z.I. Calculation of phase and amplitude correctors: Reference. - M .: Communication, 1969 .-- 116 p.

Claims (2)

1. A generator of test signals, including a source of a periodic sequence of short video pulses, characterized in that the output of this source is connected to a delay element, the output of which is connected to the input of the first electronic switch, the first output of which is connected to the first input of the second electronic switch, and the second output of the first electronic the switch is connected to the input of the phase corrector, the output of which is connected to the second input of the second electronic switch, while the output of the second electronic to the mutator is the output of the generator, and the inputs of the switching signal of the electronic switches are connected to the output of the frequency divider by two, the input of which is connected to the output of the source of the periodic sequence of short video pulses, the input of the first electronic switch normally closed with its first output, and the first input of the second electronic switch normally closed with his exit. 2. The test signal generator according to claim 1, characterized in that the source of the periodic sequence of short video pulses is made in the form of a binary pulse counter and a logical element AND with the number of inputs equal to the number of binary bits of the counter, and a separate signal is connected to the output of each of the bits of the binary pulse counter the input of the logical element AND, while the output of this logical element is the output of the source of the periodic sequence of short video pulses, and the delay element is executed n as a shift register, the clock inputs of binary counter pulses and the shift register are connected to the clock pulse generator.