RU2628434C1 - Triangular waveform generator - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: triangular waveform generator contains a controlled source of quadrature harmonic signals, the first, the second and the third calculators of the module, the first and the second adders.

EFFECT: increasing the reliability with changing frequency and amplitude of the generated signal within wide limits.

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Description

The invention relates to the field of radio engineering and computer engineering and can be used in radar, in voltage-time interval converters, pulse-width modulators, time delay devices, etc.

A device [1] is known, which contains a phase shifter (made of a phase-shifting RC chain), two half-wave rectifiers and an adder at the output of which a triangular signal is generated.

The phase shifter provides a phase shift of 90 degrees electrical angle, but only for one fixed value of the input signal frequency. When switching to a different frequency, it is necessary to reconstruct the time constant of the phase-shifting RC chain by changing the parameters of capacitance C or resistor R. A significant drawback is also the significant non-linearity of the generated signal of a triangular shape in the areas of “forward” and “return” motion of the generated signal.

A device [2] is known that contains a wide-range amplitude-independent phase shifter (made of an operational amplifier, uncontrolled and code-controlled two-terminal devices, a control unit and two resistors), two module calculators, and a differential amplifier (made of a second operational amplifier and four resistors), the output of which a quasi-triangular waveform is formed. Reactive elements (capacitance, inductance or their simulators), which are part of two-terminal devices, significantly worsen the dynamics of the shaper, that is, they “delay” the establishment of a transient process, which, along with the complexity of the practical implementation of individual blocks, can be considered certain disadvantages of the device. In addition, a signal that does not have high linearity is formed at the output of the device.

A device [3] is known, comprising a first and a second module calculator (made of half-wave rectifiers), a correction unit and a summing block (made of a subtractor and an adder), the output of which is connected to the output of a triangular signal conditioner, the first input of which is connected to the input of the first calculator module and the first input of the correction unit, and the second input with the input of the second calculator module and the second input of the correction unit, the output of which is connected to the third input of the summing unit, the first and second inputs of which connected to the outputs of the first and second calculators modules.

The shaper can operate in a wide range of input quadrature harmonic signals, but the amplitude of these signals must remain stable, which limits the capabilities of such a converter.

A device [4] is known, comprising a base unit (BB) and a correction unit (BC), the output of which is connected to the third input of the base unit, the output of which is connected to the output of a triangular waveform driver, the first input of which is connected to the first inputs of the base unit and the correction unit while the second input of the triangular waveform former is connected to the second inputs of the base unit and the correction unit.

The base unit is made of two calculators of the module, the subtractor and the adder, the first input of which is connected to the output of the subtracter, while the first calculator of the module is connected between the first input of the base unit and the first input of the subtractor, the second calculator of the module is connected between the second input of the base unit and the second input of the subtractor, moreover, the third input of the base unit is connected to the second input of the adder, the output of which is connected to the output of the triangular signal shaper.

The correction unit is made of two quadrators, a second subtractor, a second adder, a divider and a square root extraction circuit whose input is connected to the output of the second adder, while the output of the first quadrator is connected to the first input of the second subtractor and the first input of the second adder, the output of the second quadrator is connected to the second input of the second adder and the second input of the second subtractor, the output of which is connected to the first input of the divider, the second input of which is connected to the output of the square root extraction circuit, the first second inputs of the correction unit are connected to inputs of the first and second quad.

When quadrature harmonic signals are applied to the device inputs, a triangular signal is generated at its output. The operability of the triangular waveform generator is preserved when the frequency and amplitude of the quadrature harmonic signals change over a wide range, but the device is quite complex, because it contains precision non-linear blocks (two quadrators, a divider and a square root extraction circuit), which will mainly determine the cost of the triangular signal driver.

The closest device to the claimed invention in terms of essential features is, adopted as a prototype, a triangular signal shaper [5, Fig. 1], containing a controlled source of quadrature harmonic signals, two module calculators, two quadrators, a divider and three adders, while the first output of the controlled quadrature oscillation source is connected to the input of the first module calculator and the input of the first quadrator, the second output of the controlled quadrature oscillation source is connected to the input the second calculator module and the input of the second quadrator, the output of which is connected to the second input of the second adder, the output of which is connected to the first input of the divider, the second input is The second control bus is connected to the second input of the controlled source of quadrature harmonic signals, the first and second inputs of the first adder connected to the outputs, respectively the first and second calculators of the modules, and the output of the first quadrator is connected to the first input of the second adder, the output of the first adder and connected to the first input of the third adder, the output of the divider is connected to the second input of the third adder, the output of which is connected to the output bus of the signal conditioner of a triangular shape.

The operability of a triangular waveform driver is maintained when the frequency and amplitude of the quadrature harmonic signals varies widely, but the device is quite complex, because it contains precision non-linear blocks (two quadrators and a divider), which will mainly determine the cost of a triangular waveform generator .

The problem to which the invention is directed, is to increase the reliability and reduce the cost of the device under conditions of changing the frequency and amplitude of the generated signal over a wide range.

The technical result achieved by the implementation of the invention is to increase the reliability and reduce the cost of the device under conditions of changing the frequency and amplitude of the generated signal over a wide range.

The specified technical result during the implementation of the invention is achieved by the fact that in the triangular waveform generator containing a controlled source of quadrature harmonic signals, the first and second module calculators, the first and second adders, the first inputs of which are connected to the output of the first module calculator, the input of which is connected to the first output a controlled source of quadrature harmonic signals, between the second output of which and the second input of the first adder, a second module calculator is turned on, while the output of the second adder is connected to the output of the triangular waveform former, the first and second inputs of which are connected, respectively, with the first and second inputs of the controlled source of quadrature harmonic signals, a third module calculator is added, connected between the output of the first adder and the third input of the second adder, the second input of which connected to the output of the second module calculator.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, allowed to establish that the applicant did not find an analogue characterized by features identical to all the essential features of the claimed invention. Therefore, the claimed invention meets the condition of "novelty."

The introduction of the third module calculator into the proposed device, as well as the organization of new relationships between functional elements, made it possible to increase the reliability and reduce the cost of the device under conditions of changing the frequency and amplitude of the generated signal over a wide range.

The invention is illustrated by a structural diagram of a triangular waveform driver (FIG. 1) and graphs (FIG. 2, FIG. 3) explaining the principle of operation of a triangular waveform driver.

The triangular waveform generator (Fig. 1) contains a controlled source of quadrature harmonic signals 1, first 2, second 3 and third 6 calculators of modules, the first 4 and second 5 adders, the first inputs of which are connected to the output of the first calculator of module 2, the input of which is connected to the first output of the controlled source of quadrature harmonic signals 1, the second output of which is connected to the input of the second calculator of module 3, the output of which is connected to the second inputs of the first 4 and second 5 adders, while the third calculator can Uhl 6 is connected between the output of the first adder 4 and the third input of the second adder 5 whose output is connected to the output of the triangular waveform, the first and second control inputs of which are connected to respective inputs of a controlled source of harmonic signals quadrature 1.

The signal generator of a triangular shape operates as follows.

When voltages E _f and E _{m are} applied to the corresponding inputs of a triangular-shaped signal conditioner (Fig. 1) after the end of transient processes, the outputs I (t) and Q (t) are shifted 90 relative to each other at the outputs of a controlled source of quadrature harmonic signals 1 electrical degrees

- текущее значение угла в радианах; А₁ и A₂ - амплитудные значения сигналов I(t) и Q(t), зависящие от заданного значения напряжения E_m на втором входе управляемого источника квадратурных гармонических сигналов 1;

- частота формируемых сигналов I(t) и Q(t), значение которой определяется величиной напряжения E_f, приложенного к первому входу управляемого источника квадратурных гармонических сигналов 1.Where

- the current value of the angle in radians; And ₁ and A ₂ are the amplitude values of the signals I (t) and Q (t), depending on a given voltage value E _m at the second input of a controlled source of quadrature harmonic signals 1;

- the frequency of the generated signals I (t) and Q (t), the value of which is determined by the value of the voltage E _f applied to the first input of the controlled source of quadrature harmonic signals 1.

With normalized values of the amplitudes A ₁ = A ₂ = A ^* = 1, expression (1) is simplified

The generated signals I (t) and Q (t) are shown in FIG. 2 a.

At the output of the first 2 and second 3 calculators of the modules, unipolar signals M ₁ (t) and M ₂ (t) are generated (Fig. 2, b), which are fed to the corresponding inputs of the first 4 and second 5 adders.

The output of the first adder 4 signal

where k ₁₁ and k ₁₂ are the transmission coefficients, respectively, for the first and second inputs of the first adder 4.

Analysis of the synthesized signal S (t) (Fig. 2, b) obtained for the values of the coefficients k ₁₁ = k ₁₂ = 1 allows us to conclude that the signal S (t) has S-shaped (different from linear) characteristics as increasing , and in the falling sections of the generated signal and has significant non-linearity.

раз.Linearization of the signal S (t) is performed using the calculator of module 6 and the adder 5. At the output of the calculator of module 6, a unipolar signal M ₃ (t) is generated (Fig. 2c), which is fed to the third input of the second adder 5. As a result of summing the signals M ₁ (t) and M ₂ (t) it is possible to obtain (Fig. 2d) a signal V ₀ (t) = M ₁ (t) + M ₂ (t), the largest (amplitude) value of which will exceed the amplitude values of the signals M ₁ (t) and M ₂ (t) in

time.

, а коэффициент передачи по третьему входу

.The transmission coefficients for the first and second inputs of the second adder 5 must have equal values

, and the gear ratio of the third input

.

For a more visual representation of the linearization process of the signal S (t) in the graphs depicted in FIG. 3 shows the virtual signals V ₁ (t) and V ₂ (t)

.

.

Signals V ₁ (t) and V ₂ (t) have non-linearities of opposite direction (Fig. 3, b), which, as a result of summing, cancel each other, therefore, as a result of summing real signals M ₁ (t), M ₂ (t) and M ₃ (t) at the output of the second adder 5 is formed (Fig. 3, b) a linearly changing triangular waveform N (t), which is qualitatively different from the synthesized signal S (t) shown in FIG. 3 a.

The device is operable in conditions of changing the frequency and amplitude of the quadrature harmonic signals over a wide range. The proposed device, in contrast to the prototype, does not include precision expensive expensive dividing blocks (two quadrators and a divider), and also contains fewer elements, which ultimately leads to increased reliability and lower cost.

The use of the invention will improve reliability and reduce the cost of the device under conditions of changing the frequency and amplitude of the generated signal over a wide range.

Information sources

1. Shustov M.A. Additive waveform driver triangular shape. - Radio Engineering, 2003, No. 1, (p. 95 - Fig. 1).

2. Pat. 81859, Russian Federation, IPC H03K 4/06. An analog-digital additive driver of a signal of a triangular shape / Dubrovin B.C., Zyuzin A.M. - No. 2008146321/22; declared 11/24/08; publ. 03/27/09, Bull. No. 9. - 12 p., 2 ill.

3. Pat. 83669, Russian Federation, IPC H03K 4/06. Additive Triangle Shaper / Dubrovin B.C., Zyuzin A.M. - No. 2009103327/22; declared 02.02.09; publ. 06/10/09, Bull. No. 16. - 8 p., 5 ill.

4. Pat. 2541147, Russian Federation, IPC H03B 27/00. Function Generator / Dubrovin B.C., Zyuzin A.M. - No. 2013143418/08; declared 09/25/12; publ. 02/10/15, Bull. No. 4. - 10 s., 2 ill.

5. Dubrovin B.C. Amplitude and frequency controlled shaper of linearly changing symmetric signal / B.C. Dubrovin // South Siberian Scientific Bulletin. - Biysk, 2015. - No. 3 (11). - S. 21-25 (prototype).

Claims (1)

A triangular waveform generator containing a controlled source of quadrature harmonic signals, first and second module calculators, first and second adders, the first inputs of which are connected to the output of the first module calculator, the input of which is connected to the first output of the controlled source of quadrature harmonic signals, between the second output of which the second input of the first adder includes a second module calculator, while the output of the second adder is connected to the output of the triangular waveform driver, p the first and second inputs of which are connected, respectively, with the first and second inputs of a controlled source of quadrature harmonic signals, characterized in that it additionally includes a third module calculator, connected between the output of the first adder and the third input of the second adder, the second input of which is connected to the output of the second calculator module.

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