RU70060U1 - SINGLE BAND FORMER - Google Patents

Abstract

The utility model relates to radio engineering, and more specifically to devices for the formation of modulated signals. A single-band signal generator comprises a signal converter and a high-frequency signal generator, wherein the high-frequency signal generator has first and second inputs, the signal converter has first and second outputs, the first output of the signal converter is connected to the first input of the high-frequency signal generator, and the second output of the signal converter is connected to the second the input of the shaper of the high-frequency signal, while the input of the signal converter is the input of the shaper of a single-band s drove, the output of the shaper of the high-frequency signal is the output of the shaper of a single-band signal. The result is a decrease or absence of a side signal from the generated single-band signal due to incomplete suppression of the second sideband.

Description

The utility model relates to radio engineering, and more specifically to devices for the formation of modulated signals.

Currently, single-band signals are widely used in radio engineering, single-band communication systems are widespread. Several methods are known for generating a single-band signal (Bunimovich S., Yaylenko L. Amateur single-band radio communication technology. - M.: DOSAAF, 1970. - 312 p.), Such as the filter method, phase method, phase-filter method, synthetic method. These methods for generating a single-band signal are implemented using many different devices.

The main elements of device circuits forming a single-band signal by the filter method are mixers, generators, bandpass filters and amplifiers.

The main elements of device circuits forming a single-band signal by the phase method are amplitude or balanced modulators, low-frequency and high-frequency phase shifters, generators and amplifiers.

The main elements of device circuits forming a single-band signal by the phase-filter method are balanced modulators, low-frequency and high-frequency phase shifters, low-pass filters or band-pass filters, generators and amplifiers.

The main elements of the circuits of devices forming a single-band signal by the synthetic method are balanced modulators, generators, amplifiers, bandpass filters, envelope detectors, limiters, discriminators, frequency modulators.

The closest in technical essence and the achieved positive result to the claimed model is a device for receiving a single-band signal by the phase method (Bunimovich S., Yaylenko L. Technique of amateur single-band radio communication. - M .: DOSAAF, 1970. - 312 p., P. 119- 120). The scheme of the device for receiving a single-band signal by the phase method includes a microphone, a modulator (low-frequency amplifier), a low-frequency phase shifter, a high-frequency generator, a high-frequency phase shifter, the first and second balanced modulators, the microphone output being connected to the input of the low-frequency amplifier, the output of the low-frequency amplifier being connected to the input a low-frequency phase shifter, which has two outputs, one of which is connected to the first input of the first balanced modulator, and the other output is connected to the first input in second balanced modulator output

the high-frequency generator is connected to the input of the high-frequency phase shifter, which has two outputs, one of which is connected to the second input of the first balanced modulator, and the other output is connected to the second input of the second balanced modulator, while the outputs of the balanced modulators are combined on a common external load.

This device operates as follows. The audio frequency voltage from the microphone is supplied to a low-frequency amplifier (modulator) and then fed to a low-frequency phase shifter having two outputs, the low-frequency voltages at these outputs are 90 degrees out of phase with respect to each other. One of these voltages is supplied to the first balanced modulator, the second of these voltages is supplied to the second balanced modulator. The high-frequency voltage is supplied to the same balanced modulators through a high-frequency phase shifter. Its output voltages also have a 90 degree phase shift between themselves, one of these voltages is supplied to the first balanced modulator, the second of these voltages is supplied to the second balanced modulator. In each balanced modulator, the voltages of two sidebands without a carrier are obtained, moreover, the voltages of one sidebands (lower or upper) at the output of the balanced modulators are out of phase, and the voltages of the other sidebands (respectively, upper or lower) at the output of the balanced modulators are in phase. Both balanced modulators operate on a common external load, due to which the output of the entire device has only one sideband signal.

Switching to the generation of another sideband in this device is carried out by changing the phase shift of one of the signals from the high-frequency phase shifter or low-frequency phase shifter by 180 degrees. In this case, the vibrational vectors of the sidebands in one or another balanced modulator change directions in the opposite direction, and as a result of addition, the vibrations of the other sideband are distinguished at the output of the entire device.

The disadvantages of this device include the practical difficulty of suppressing the sideband by more than 40-45 dB and, as a result, the side signal of the device outside the band of the communication channel when the device is operating in transmitters of single-band signals, increased requirements for the details of individual components of the device, in particular, elements of a low-frequency phase shifter, instability of suppression of the side strip and the carrier during operation of the device.

The problem solved by the author when creating a single-band signal shaper was to create a single-band signal shaper providing a smaller side signal (caused by incomplete suppression of one side band) outside the spectrum of the generated single-band signal or the complete absence of the side signal (caused by incomplete suppression) outside the spectrum of the generated single-band signal one side strip). This problem was solved by creating the following device (the corresponding drawings of the schemes of the shaper of a single-band signal are given).

A single-band signal shaper (Fig. 1) containing a signal converter 1 and a high-frequency signal shaper 2, while the high-frequency signal shaper has first and second inputs, the signal converter has first and second outputs, the first output of the signal converter is connected to the first input of the high-frequency signal shaper, the second output of the signal converter is connected to the second input of the shaper of the high-frequency signal, while the input of the signal converter is the input of the shaper If the signal is high, the high-frequency signal conditioner output is the output of a single-band signal conditioner, the signal converter being a digital device, the high-frequency signal conditioner (Fig. 2 and 3) containing the first and second balanced modulators 3 and 4, a high-frequency generator 5, and a high-frequency phase shifter 6 having two outputs, the output of the high-frequency generator connected to the input of the high-frequency phase shifter, the first output of the high-frequency phase shifter connected to the high-frequency With the input of the first balanced modulator, the second output of the high-frequency phase shifter is connected to the high-frequency input of the second balanced modulator, and the signal from the second output of the high-frequency phase shifter is + 90 degrees out of phase with respect to the signal from the first output of the high-frequency phase shifter plus 90 degrees relative to the signal from the second output of the high-frequency phase shifter.

A special case of the implementation of a single-band signal shaper is a single-band signal shaper (Fig. 4), supplemented by an analog-to-digital converter 7, and the input of the analog-to-digital converter is the input of a single-band signal shaper, and the output of the analog-to-digital converter is connected to the input of the signal converter.

The implementation of the signal converter in digital form is intended for digital processing of the input digital signal in it. Signal converter implementation

supplemented by an analog-to-digital converter is intended for digital processing in the signal converter of an input analog or discrete signal. It is assumed that the input signal of the shaper of a single-band signal is a modulating signal.

Special cases of the implementation of the shaper of a single-band signal represented by the distinctive features contained in the shaper of the high-frequency signal or in the signal converter are presented in the following variants.

Shaper of a high-frequency signal (Fig. 2 and 3). A high-frequency signal generator characterized in that it contains the first and second digital-to-analog converters 8 and 9, the first and second low-pass filters 10 and 11, an adder or subtractor 12, and the output of the first digital-to-analog converter is connected to the input of the first low-pass filter, output the second digital-to-analog converter is connected to the input of the second low-pass filter, the output of the first low-pass filter is connected to the low-frequency input of the first balanced modulator, the output of the second low-pass filter is connected nen with the low-frequency input of the second balanced modulator, the outputs of the first and second balanced modulators are connected to the inputs of the adder or subtracter, and the output of the adder or subtractor is the output of the high-frequency signal generating device, the input of the first digital-to-analog converter is the first input of the high-frequency signal generating device, the input of the second digital -analog converter is the second input of the high-frequency signal generating device.

The first version of the signal converter (Fig. 2). A signal converter characterized in that it comprises a 90 degree phase shifter 13 having one output, first, second, third and fourth multipliers 14, 15. 16 and 17, first and second adders 18 and 19, a generator 20 having first, second and third outputs, moreover, the signal from the second output of the generator is phase shifted by plus 90 degrees relative to the signal from the first output of the generator, the signal from the third output of the generator is phase shifted by 180 degrees relative to the signal from the first output of the generator, the first input of the first multiplier, the first input One of the third multipliers and the input of the phase shifter are 90 degrees combined and are the input of the signal converter, the first output of the generator is connected to the second input of the first multiplier, the second output of the generator is connected to the second inputs of the second and third multipliers, the third output of the generator is connected to the second input of the fourth multiplier, the output of the phase shifter 90 degrees connected to the first inputs

the second and fourth multipliers, the outputs of the first and second multipliers are connected to the inputs of the first adder, the output of the first adder being the first output of the signal converter, the outputs of the third and fourth multipliers are connected to the inputs of the second adder, the output of the second adder being the second output of the signal converter.

The second version of the signal converter (Fig. 3). The signal converter differs from the first variant of the signal converter in that instead of two adders, two subtractors are introduced, the first output of the generator is connected to the second input of the second multiplier, the second output of the generator is connected to the second inputs of the first and fourth multipliers, the third output of the generator is connected to the second input of the third multiplier , the outputs of the first and second multipliers are connected to the inputs of the first subtractor 21, and the output of the first subtractor is the first output of the signal converter, moves the third and fourth multipliers coupled to the second input of subtractor 22, the output of the second subtractor is the second output of the signal converter.

The third version of the signal converter is a digital processor that executes an algorithm for processing the input digital signal similar to the algorithm for processing the input digital signal performed by the signal converter specified in the first or second variants of the signal converter.

Shaper single-band signal operates as follows.

When executing a shaper of a single-band signal as part of a signal converter (first or second options) and a shaper of a high-frequency signal, the algorithm for processing the input signal by the signal converter is implemented in digital form. At the same time, in the signal converter, the generator generates at its outputs digital signals that are a digital representation of sinusoidal signals, the input digital signal is processed, the output signals are also digital, it is assumed that the input digital signal is a digital representation of an analog or discrete modulating signal.

In the signal converter, the input signal is fed to the first inputs of the first and third multipliers and to the input of the phase shifter by 90 degrees. In the phase shifter 90 degrees the input signal is phase shifted by plus 90 degrees and is fed to the first inputs of the second and fourth multipliers. In the multipliers, the multiplication of the input signals arriving at the first inputs of the multipliers by the signals arriving at the second inputs of the multipliers from the outputs of the generator occurs. At the exits

multipliers get two-way signals. Depending on the implementation of the signal converter using adders or subtracters, two signals from two multipliers in which the upper sidebands are in antiphase to each other are fed to the inputs of each adder or two signals from two multipliers in which the lower sidebands are in the inputs of each adder out of phase to each other. In the adders, the input signals are added and the outputs of each adder produce a single-band signal (a signal with a lower sideband). In the first subtractor, the signal from the output of the first multiplier is subtracted from the signal from the output of the second multiplier or vice versa, in the second subtracter, the signal from the output of the third multiplier is subtracted from the signal from the output of the fourth multiplier or vice versa and a single-band signal is obtained at the outputs of each subtractor (signal with a lower sideband) . In this case, the signals from the outputs of the adders or subtracters differ from each other only by the presence of a phase shift of 90 degrees relative to each other. Further, the signals from the first and second outputs of the signal converter are supplied respectively to the first and second inputs of the shaper of the high-frequency signal. The input digital signals of the high-frequency signal driver, passing through digital-to-analog converters and low-pass filters, are converted into analog or discrete single-band signals. The signals from the outputs of the first and second low-pass filters are respectively supplied to the first and second low-frequency inputs of the balanced modulators, and in the balanced modulators these signals are multiplied by the signals supplied to the high-frequency inputs from the outputs of the phase shifter. In this case, depending on the phase relations of the input signals of the shaper of the high-frequency signal relative to each other and on the phase relations of the output signals of the phase shifter relative to each other, two two-way signals are formed at the outputs of the balanced modulators, in which the lower sidebands or upper sidebands are out of phase to each other. Depending on the execution of the high-frequency signal generator using an adder or a subtractor, the adder sums up the input signals and a single-band signal is obtained at the adder output (a signal with a lower or upper sideband), in the subtracter, the signal from the output of the first balanced modulator is subtracted from the signal from the output of the second balanced modulator or vice versa and the output of the subtractor produces a single-band signal (a signal with a lower or upper sideband).

When executing a shaper of a single-band signal using a signal converter, the digital processor acts as it (the third

option), the algorithm for processing the input signal by the signal converter is similar to the algorithm for processing the input signal performed by the signal converter specified in the first or second variants of the signal converter.

When performing a single-band signal shaper using an analog-to-digital converter, a signal converter and a high-frequency signal shaper, the processing of the input signal differs in that, first, the analog-to-digital converter performs an analog-to-digital conversion of the input signal, and then the received digital signal from the output of the analog-to-digital converter fed to the input of the signal converter, it is assumed that the input signal of the shaper of a single-band signal is an Ogove or discrete baseband signal.

Optimal characteristics of a single-band signal driver.

For a signal converter, the frequency of a sinusoidal signal whose digital form is the signal at the generator outputs should be chosen equal to the average frequency of the spectrum of that analog or discrete signal, the digital form of which is the input digital signal. Then the spectrum of the suppressed sideband of the input signals of the adder or subtractor at the output of the adder or subtractor of the shaper of the high-frequency signal occupies the same frequency interval as the spectrum of the generated single-band signal. Thus, the solution of the problem posed by the author when creating a shaper of a single-band signal is achieved.

Functions of a shaper of a single-band signal.

The described operation of a single-band signal shaper relates in particular to the task of generating a single-band signal at frequencies depending on the frequency of a high-frequency generator of a high-frequency signal shaper from an input modulating signal. That is, the shaper of a single-band signal performs the main function - the function of a single-band modulation and is a single-band modulator. An additional function of a single-band signal shaper is demodulation of a single-band signal. That is, the shaper of a single-band signal is also a single-band demodulator. The single-band signal generator also performs a single-band frequency conversion, while the spectrum of the input signal is transferred both up and down in frequency, while the input signal can be either single-band or any other. That is, the shaper of a single-band signal is also a single-band frequency converter.

Claims (7)

1. A single-band signal generator comprising a signal converter and a high-frequency signal generator, wherein the high-frequency signal generator has first and second inputs, the signal converter has first and second outputs, the first output of the signal converter is connected to the first input of the high-frequency signal generator, and the second output of the signal converter is connected with the second input of the shaper of the high-frequency signal, while the input of the signal converter is the input of the shaper about the signal, the output of the shaper of the high-frequency signal is the output of the shaper of the single-band signal, the signal converter being a digital device, the shaper of the high-frequency signal containing the first and second balanced modulators, a high-frequency generator and a high-frequency phase shifter having two outputs, and the output of the high-frequency generator connected to the input of the high-frequency phase shifter , the first output of the high-frequency phase shifter is connected to the high-frequency input of the first alan modulator, the second output of the high-frequency phase shifter is connected to the high-frequency input of the second balanced modulator, and the signal from the second output of the high-frequency phase shifter is + 90 degrees out of phase with respect to the signal from the first output of the high-frequency phase shifter is + 90 degrees out of phase relative to the signal from the second output of the high-frequency phase shifter. 2. A single-band signal shaper according to claim 1, characterized in that an analog-to-digital converter is additionally introduced, wherein the input of the analog-to-digital converter is an input of a single-band signal shaper, and the output of the analog-to-digital converter is connected to the input of the signal converter. 3. The single-band signal shaper according to claim 1, characterized in that the high-frequency signal shaper further comprises first and second digital-to-analog converters, a first and second low-pass filters, an adder or a subtracter, the output of the first digital-to-analog converter being connected to the input of the first low-pass filter, the output the second digital-to-analog converter is connected to the input of the second low-pass filter, the output of the first low-pass filter is connected to the low-frequency input of the first balanced module torus, the output of the second low-pass filter is connected to the low-frequency input of the second balanced modulator, the outputs of the first and second balanced modulators are connected to the inputs of the adder or subtracter, and the output of the adder or subtractor is the output of the high-frequency signal generating device, the input of the first digital-to-analog converter is the first input of the high-frequency generating device signal, the input of the second digital-to-analog converter is the second input of the high-frequency shaping device th signal. 4. The single-band signal generator according to claim 1, characterized in that the signal converter comprises a 90 degree phase shifter having one output, first, second, third and fourth multipliers, a generator having first, second and third outputs, the signal from the second output the generator is phase-shifted by plus 90 degrees relative to the signal from the first output of the generator, the signal from the third output of the generator is phase-shifted by 180 degrees relative to the signal from the first output of the generator, the first input of the first multiplier, the first the input of the third multiplier and the input of the phase shifter 90 degrees are combined and are the input of the signal converter, the output of the phase shifter 90 degrees connected to the first inputs of the second and fourth multipliers. 5. The single-band signal generator according to claim 4, characterized in that the signal converter further comprises first and second adders, the outputs of the first and second multipliers being connected to the inputs of the first adder, the output of the first adder being the first output of the signal converter, the outputs of the third and fourth multipliers connected to the inputs of the second adder, and the output of the second adder is the second output of the signal Converter, and the first output of the generator is connected to the second input of the first multiplier, the second output of the generator is connected to the second inputs of the second and third multipliers, the third output of the generator is connected to the second input of the fourth multiplier. 6. A single-band signal generator according to claim 4, characterized in that the signal converter further comprises first and second subtracters, the outputs of the first and second multipliers being connected to the inputs of the first subtracter, the output of the first subtractor being the first output of the signal converter, the outputs of the third and fourth multipliers connected to the inputs of the second subtracter, and the output of the second subtractor is the second output of the signal converter, the first output of the generator is connected to the second input of the second ne emnozhitelya, the second output of the generator is connected to second inputs of the first and fourth multipliers, the third output of the generator is connected to a second input of the third multiplier. 7. The single-band signal generator according to claim 1, characterized in that the signal converter is a digital processor that performs an input digital signal processing algorithm similar to the input digital signal processing algorithm performed by the signal converter specified in clause 5 or clause 6.