SU995356A1 - Bi-pulse signal-to-binary signal converter - Google Patents

Description

1 G controlled factor integrator 2, comparators 3 and 4, source 5 Reference voltage, RS-three ger b, OR element, and source 5 reference voltage consists of diodes & E of capacitors 10 and 11 and resistive dividers of 12, 13, 14 and 1 voltages. The device works as follows. The received bi-pulse signal (Fig. 2a) arrives at amplifier 1, after which the amplified signal (Fig. 26) is tagged; by the integrator 2 without reset (Fig. 2c), the received signal is compared with 1 ommparators 3 and 4 with reference voltage) and and 02 coming from source 5. At the output of the comparator 3, when the integrated signal (Fig. 2c) exceeds the reference voltage U a pulse is formed (Fig. 2d). At the output of the comparator 4, a pulse (Fig. 2d) is formed when the integrated signal is less than the voltage. 1/2. The resulting impulses (Fig. 2d id) switch the RS flip-flop 6., which forms the output binary signal (Fig. 2e), which is C9der: its in bi-pulse. In addition, a clock signal is generated (FIG. 2g), obtained by combining the OR 7 signals from the outputs of the comparator 3 and 4. Depending on the frequency of the input signal, the duration of the impulses changes (Fig. 2a, 26), and therefore amplitude; 1a of the pulses at the output of the inter- tor 2 with the constant parameter in. tegrirovayi. The device remains operable for as long as the signal peaks at the integrator output are greater than the reference voltages, i.e. sufficient to form at the outputs of the comparators 3 and 4. At the same time, the duty cycle of the output binary signal is practically unchanged (because; duration; 6; the pulses at the outputs of the comparators | 3 and 4 change to the same value; otherwise); but the duty cycle of the | ov signal at the output of the OR element changes. The frequency range of the practical depends on the integrator's dynamic range (downward and frequency) and on the sensitivity of the comparators (upward, ca;). To reduce the requirements for the integrator and the CC 4, it is necessary to ensure the maintenance of a constant amplitude | beats at the output of the integrator 2 by connecting its output to the adjustment input of the amplifier Amplifier 1. This ensures that the overload of the integrator 2 is eliminated at low frequencies and you have the level of the signal at the inputs of the comparators and 3 and 4 at high frequencies, i.e. the working frequency decay in practical implementation (Fig. 2a, 2c). In a certain frequency range, in order to reduce the effect of the input signal frequency on the duty cycle of the clock signal at the output of the element OR 7 without using amplifiers with adjustable gain (a rather complicated device), a peak detector, such as shown, for example, can be used as a reference voltage source. FIG. 2. The peak detector provides the selection of the envelopes of the signal at the output of the integrator 2. In this case, the voltages U and Ug taken from resistive dividers 12, 13 / and 14, 15 change in proportion to the change in the envelope of the integrated signal, i.e. its amplitudes. Thus, at any amplitude of the integrated signal, the reference voltages are less than the peak value (for example, two times with equal resistance of the resistors 12-15), and the duty cycle remains almost unchanged (Figs. 2a, 2d). Based on the foregoing, it is clear that the proposed device is operable in a wide frequency range, so that the upper frequency can be several times higher than the lower frequency. The practical limits depend on the dynamic range of the integrator and the sensitivity of the comparators, as well as on the depth of the gain control of the input amplifier and the quality of the peak detector. . The use of the proposed device in test equipment for digital information transmission systems will reduce its cost by using one proposed device at several frequencies instead of separate devices of the same purpose for each frequency. In addition, the functionality of the instrumentation equipment is expanded, for example, due to the possibility of examining the operability of a digital system in the range of frequencies that are nearly 1 1 (especially hierarchical), etc. Invention A bi-pulse signal converter into a binary signal, a soda integrator, two comparators, the first inputs of which are connected to the corresponding outputs of a voltage source, and an RS trigger, the integrator's output connected to the second input of the first comparator, and the output of the second comparator connected to one from the RS-flip-flop inputs, characterized in that, in order to expand the range of operating frequencies

converter, an amplifier with a gain control is introduced, the output of which is connected to an integrator input, the output of which is connected to the second input of the second comparator and control of the amplifier with a control factor: the gain, and the output of the first comparator is connected to another input of the RS trigger.

Information sources, . taken into account in the examination

1. USSR author's certificate 259133, cl. H 04 L 25/08, 1E69.

2. USSR author's certificate No. 799159, cl. H 04 L 25/00, 1975 (prototype).

Claims (1)

Claim A bi-pulse signal to binary signal converter comprising an integrator, two comparators, the first inputs of which are connected to the corresponding outputs of the reference voltage source, and an RS trigger, the integrator output being connected to the second input of the first comparator, and the output of the second comparator connected to one of the RS- inputs trigger, characterized in that, in order to expand the operating frequency range of the converter, an amplifier with a controlled gain factor * * is introduced, the output of which is connected to the integrator input, the output of which connected to the second input of the second comparator and the control input of a controlled amplifier 5 lyaemm gain, and the output of the first comparator is connected to another input of RS-latch. ''