RU2577202C1 - Radio transmitter - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to radio engineering and can be used in radiotelemetric systems for obtaining information from mobile objects. Radio transmitting device includes output power amplifier, parameter control unit, control unit signal frequency switch, the first frequency synthesizer, second frequency synthesizer, an amplitude modulator, the first controlled attenuator, the second controlled attenuator, the first controlled frequency divider, the second controlled frequency divider.

EFFECT: technical result is increased suppression of parasitic stray radiation of the neighbouring transmitter channel.

1 cl, 2 dwg

Description

The invention relates to the field of radio engineering and can be used in radio telemetry systems to obtain information from moving objects.

A radio transmitting device [1] is known, comprising a control unit, a control pulse shaper, an OR element, a modulating pulse shaper, a block of RF generators, and a series-connected switch of RF oscillations, a multiplier, an amplitude modulator, and an output power amplifier. To increase the noise immunity of the communication channel under the influence of the reflected signal in the transmitter, time-frequency coding of the output signal is carried out by introducing additional RF generators and a frequency switching circuit into the transmitter. The disadvantage of this device is the relatively high level of side spurious components that occur when repeatedly multiplying the signal to the output frequency, which reduces the noise immunity of the communication channel.

The closest in technical essence is a transmitter with pulse-code modulation [2]. The device comprises an output power amplifier, a parameter control unit, the output of which is connected to the input of the signal control unit, the first output of the signal control unit is connected to the frequency setting input of the frequency synthesizer and a second frequency synthesizer, a frequency switch and controlled attenuators are introduced, and the third output of the signal control unit is connected with the frequency setting input of the second frequency synthesizer, the fourth output is connected to the control input of the frequency switch, the output of the frequency switch is connected to the signal the first input of the amplitude modulator, and the output of the amplitude modulator to the input of the output power amplifier, the first controlled attenuator is connected between the output of the first frequency synthesizer and the first input of the frequency switch, and the second controlled attenuator is turned on between the output of the second frequency synthesizer and the second input of the frequency switch, with the fifth output the signal control unit is connected to the control input of the first controlled attenuator, and the sixth output of the signal control unit is connected to the control input of the second unit the inventive attenuator, while the output of the output power amplifier is the output of the device.

The disadvantage of the transmitting device [2] is the insufficient isolation between the channels, which leads to a decrease in the reliability of obtaining telemetric information when receiving input signals in a large dynamic range.

The technical result of the invention is to increase the reliability of obtaining telemetric information in a large dynamic range of input signals by increasing the suppression of spurious spurious emission from an adjacent channel of the transmitter.

The technical result is achieved in that the radio transmitting device comprises an output power amplifier, a parameter control unit. The output of the parameter control unit is connected to the input of the signal control unit. The first output of the signal control unit is connected to the control input of the frequency switch, the second to the input of the frequency setting of the first frequency synthesizer, the third to the input of the frequency setting of the second frequency synthesizer, the fourth output is connected to the control input of the amplitude modulator, the signal input of which is connected to the output of the frequency switch. The output of the amplitude modulator is connected to an output power amplifier, the output of which is the output of the device. The first input of the frequency switch is connected to the output of the first controlled attenuator, and the second input of the frequency switch is connected to the output of the second controlled attenuator. The fifth output of the signal control unit is connected to the control input of the first controlled attenuator. The sixth output of the signal control unit is connected to the control input of the second controlled attenuator. A first controlled frequency divider is introduced into the radio transmitting device between the output of the first frequency synthesizer and the input of the first controlled attenuator, and a second controlled frequency divider is introduced between the output of the second frequency synthesizer and the input of the second controlled attenuator. The seventh output of the signal control unit is connected to the control input of the first controlled frequency divider, and the eighth output of the signal control unit is connected to the control input of the second controlled frequency divider.

In FIG. 1 shows a block diagram of a radio transmitting device.

In FIG. 2 shows stress plots explaining the operation of the device.

The device of FIG. 1 contains a parameter control unit 1, the output of which is connected to the input of the signal control unit 2, the first output of which is connected to the control input of the frequency switch 3. The second output of the signal control unit is connected to the frequency setting input of the first frequency synthesizer 4.

The third output of the signal control unit 2 is connected to the frequency setting input of the second frequency synthesizer 5, the fourth to the control input of the amplitude modulator 6, the fifth to the control input of the first controlled attenuator, and the sixth to the control input of the second controlled attenuator. The output of the frequency switch 3 is connected through the signal input of the amplitude modulator 6 to the output power amplifier 7. Between the output of the first frequency synthesizer 4 and the input of the first controlled attenuator 8, the first controlled frequency divider 9 is connected. Between the output of the second frequency synthesizer 5 and the input of the second controlled attenuator 10, the second controlled frequency divider 11. The seventh output of the signal control unit 2 is connected to the control input of the first controlled frequency divider 9, and the eighth to the control input of the second control frequency converter 11.

The device operates as follows.

Parameter control unit 1 forms a group of pulses consisting of code and information pulses (Fig. 2a), which are fed to signal control unit 2. The signal control unit generates frequency setting codes for synthesizers 4 and 5. Frequency synthesizer 4 generates a signal with output frequency of transmitter F1 and a frequency synthesizer 5 with an output frequency of F2.

The frequency synthesizers work continuously simultaneously, and their signals are switched by the frequency switch 3. The signal of the frequency synthesizer 4 is supplied to the frequency switch 3 through the controlled frequency divider 9 and the controlled attenuator 8, and the signal of the synthesizer 5 through the controlled frequency divider 11 and the controlled attenuator 10. The control voltage to the frequency switch is shown in FIG. 26. The beginning of the code pulses and the first information pulse determine the time intervals during which signals of a certain frequency from one of the frequency synthesizers are fed to the amplitude modulator 6. So at intervals of t ₀ -t ₁ and t ₃ -t _{4 the} signal at the frequency of the first frequency synthesizer 4 F1 is supplied to the amplitude modulator 6, and at the interval t ₁ -t _{3 the} signal is at the frequency of the second frequency synthesizer 5 F2.

To obtain a pulse signal from the transmitter, an amplitude modulator is included in the circuit, 6 and then the pulse signal (Fig. 2f) is amplified by the output power amplifier 7. The control voltage from the signal control unit 2 to the amplitude modulator 6 is shown in FIG. 2c. The control voltage to the controlled attenuator 8 is shown in FIG. 2d, and on the controlled attenuator 10 - in FIG. 2d In the operating time interval of the transmitter at the frequency F1, the controlled attenuator 8 has the minimum attenuation, and the controlled attenuator 10 has the maximum, thereby increasing the suppression of the side spurious component of the frequency of the transmitter signal F2.

In the time interval of operation of the transmitter at a frequency of F2, the controlled attenuator 10 has a minimum attenuation, and the controlled attenuator 8 has a maximum attenuation, thereby increasing the suppression of the side parasitic component of the frequency F1.

The control voltage to the controlled frequency divider 9 is shown in FIG. 2g, and on a controlled frequency divider 11 - in FIG. 2z. In the operating time interval of the transmitter at the frequency F1, on a controlled frequency divider 9, a frequency division coefficient is set equal to, for example, one, and on a controlled frequency divider 11 a frequency division coefficient is set equal to, for example, two. The spurious side frequency of the transmitter signal, now equal to F2 / 2 and additionally suppressed by the controlled attenuator 10, will be significantly attenuated at the receiver input compared to the spurious frequency signal F2 in the prototype circuit due to the large detuning of the spurious side signal from the frequency signal F1.

In the operating time interval of the transmitter at a frequency of F2, a frequency division coefficient equal to one is set on the controlled frequency divider 11, and a frequency division coefficient equal to two is set on the controlled frequency divider 9. The secondary spurious frequency of the transmitter, equal to F1 / 2 and additionally suppressed by the controlled attenuator 8, will be significantly attenuated at the input of the receiver compared to the spurious frequency signal F1 in the prototype circuit. The introduction of controlled frequency dividers with the indicated connections into the circuit significantly increases the dynamic range of the input signals of the communication channel during reception, which increases the reliability of obtaining telemetric information.

Newly introduced blocks can be performed on traditional available chips.

Information sources

1. Patent No. 2113056 of the Russian Federation. IPC Н04В 7/00. Radio Transmitting Device / Borisov V.F., Chernov A.V. // Publ. 06/10/98 Bull. No. 16.

2. Patent No. 2435300 of the Russian Federation. IPC Н04В 1/02. Radio Transmitting Device / Chernov A.V., Vasiliev B.C., Baranov V.N. // Publ. 11/27/2011 Bull. No. 33 (prototype).

Claims (1)

A radio transmitting device comprising an output power amplifier, a parameter control unit, the output of which is connected to the input of the signal control unit, and the first output of the signal control unit is connected to the control input of the frequency switch, the second to the input of the frequency setting of the first frequency synthesizer, the third to the input of the frequency setting the second frequency synthesizer, the fourth output is connected to the control input of the amplitude modulator, the signal input of which is connected to the output of the frequency switch, and the output of the amplitude mode the radiator is connected to an output power amplifier, the output of which is the output of the device, the first input of the frequency switch is connected to the output of the first controlled attenuator, and the second input of the frequency switch is connected to the output of the second controlled attenuator, while the fifth output of the signal control unit is connected to the control input of the first controlled attenuator and the sixth output of the signal control unit is connected to the control input of the second controlled attenuator, characterized in that in the radio transmitting device between the output of the first frequency synthesizer and the input of the first controlled attenuator, a first controlled frequency divider is introduced, and between the output of the second frequency synthesizer and the input of the second controlled attenuator a second controlled frequency divider is introduced, while the seventh output of the signal control unit is connected to the control input of the first controlled frequency divider, and the eighth output of the signal control unit is connected to the control input of the second controlled frequency divider.

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