CN205071007U - Handheld radio comprehensive tester - Google Patents

Abstract

The utility model provides a handheld radio comprehensive tester, join local oscillator module, power module and input and output modules including signal processing module, radio frequency front end module, frequency, signal processing module simultaneously with radio frequency front end module, the local oscillator module of frequently joining, power module, input and output modules connect, power module simultaneously still with it connects frequently to join the local oscillator module, frequently join the local oscillator module with the radio frequency front end module is connected, the radio frequency front end module is used for receiving or sending radio signal, it is used for doing frequently to join the local oscillator module the radio frequency front end module provides the mixing signal, signal processing module is used for controlling the operation of each module and right the signal that the radio frequency front end module transmitted carries out analysis processes. The utility model discloses a multiple measurement function's set realizes the measurement of multiple functions.

Description

Handheld radio comprehensive tester

Technical Field

The utility model relates to an electronic measuring instrument, in particular to handheld radio comprehensive tester.

Background

At present, a single test is adopted in a field test instrument of a communication device, one instrument only measures a few functions, and measurement of multiple functions cannot be realized.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve and can not be on same instrument to the measurement of multiple functions, provide a handheld radio comprehensive tester.

In order to solve the technical problem, the utility model provides a following technical scheme:

a hand-held radio comprehensive tester comprises a signal processing module, a radio frequency front end module, a frequency parameter local oscillator module, a power supply module and an input/output module; the signal processing module is simultaneously connected with the radio frequency front-end module, the frequency parameter local oscillator module, the power supply module and the input/output module; the power supply module is also connected with the frequency-parameter local oscillator module, and the frequency-parameter local oscillator module is connected with the radio-frequency front-end module; the radio frequency front end module is used for receiving or transmitting radio signals; the frequency parameter local oscillator module is used for providing a frequency mixing signal for the radio frequency front end module, and the signal processing module is used for controlling the operation of each module and analyzing and processing the signal transmitted by the radio frequency front end module.

Furthermore, the comprehensive tester also comprises a communication module, wherein the communication module is connected with the signal processing module and is used for communicating the comprehensive tester with the outside.

Further, the input/output module comprises an input module and an output module, wherein the input module is a keyboard; the output module is a display.

The radio frequency front end module is provided with an antenna port, a T/R port and a standing wave port.

Furthermore, the radio frequency front end module comprises a T/R input/output module, an antenna input/output module and a standing wave input/output module; the T/R input/output module adopts a T/R port to carry out radio frequency input/output; the antenna input and output module adopts an antenna port to carry out radio frequency input and output; and the standing wave input and output module adopts a standing wave port to carry out standing wave input and output.

Further, the T/R input/output module comprises a T/R input module and a T/R output module, wherein,

the T/R input module comprises a T/R port, an attenuator, a power divider, a power monitoring circuit, a front-end conditioning circuit, a down-conversion circuit and an intermediate-frequency conditioning circuit; the T/R port is connected with the input end of the power divider through the attenuator, one output end of the power divider is connected with the power monitoring circuit, and meanwhile, the other output end of the power divider is sequentially connected with the front-end conditioning circuit, the down-conversion circuit and the intermediate-frequency conditioning circuit;

the T/R output module comprises a frequency synthesizer, a calibration circuit, a frequency conversion filter circuit, an amplitude control circuit, a power divider, an attenuator and a T/R port which are connected in sequence;

and the T/R port, the attenuator and the power divider in the T/R input module and the T/R output module are shared.

Further, the antenna input/output module comprises an antenna input module and an antenna output module; wherein,

the antenna input module comprises an antenna port, a first directional coupler, a front end conditioning circuit, a down-conversion circuit and an intermediate frequency conditioning circuit which are sequentially connected;

the antenna output module comprises a frequency synthesizer, a calibration circuit, a frequency conversion filter circuit, an amplitude control circuit, a first directional coupler and an antenna port which are connected in sequence;

the antenna port and the first directional coupler in the antenna input module and the antenna output module are shared, and meanwhile, a high-power protection circuit is connected between the antenna port and the first directional coupler in parallel.

Further, the standing wave input and output module comprises a standing wave input module and a standing wave output module; wherein,

the standing wave output module comprises a frequency synthesizer, a calibration circuit, a variable frequency filter circuit, an amplitude control circuit, a second directional coupler and a standing wave port which are connected in sequence;

the standing wave input module comprises a standing wave port, a second directional coupler and a logarithmic detector which are sequentially connected; the logarithmic detector is simultaneously connected with the amplitude difference monitoring module and the phase difference monitoring module;

the standing wave output module and the standing wave input module share a standing wave port and a second directional coupler, and a reverse power protection circuit is connected between the standing wave port and the second directional coupler in parallel.

The power supply module comprises a switching power supply; the switch power supply is simultaneously connected with the battery and the adapter and is used for controlling the on-off of the power supply of the comprehensive tester; the battery is used for passing battery power supply for the comprehensive tester, and the adapter of saying is used for the comprehensive tester passes through 220V commercial power circular telegram.

The comprehensive tester also comprises an audio generation module and an audio measurement module;

the audio generation module is connected with the signal processing module and used for generating audio with set frequency and outputting the audio

The audio measuring module is connected with the signal processing module and is used for sampling and analyzing the received audio signals.

The utility model discloses total 6 types of basic test pattern and a system setup mode: the 7-class basic measurement mode is as follows: a receive test mode, a transmit test mode, a duplex test mode, an audio mode, a waveform analysis mode, a spectral analysis mode, a standing wave analysis mode.

Compared with the prior art, the utility model discloses a multiple measurement function's set realizes multiple function's measurement.

Description of the drawings:

fig. 1 is a structural block diagram of the comprehensive tester provided by the utility model.

Fig. 2 is a block diagram of a radio frequency front end module.

Detailed Description

The following provides a brief description of the present invention with reference to fig. 1 and 2.

A hand-held radio comprehensive tester comprises a signal processing module 1, a radio frequency front end module 3, a frequency parameter local oscillator module 2, a power supply module 4 and an input/output module 5; the signal processing module 1 is simultaneously connected with the radio frequency front end module 3, the frequency parameter local oscillator module 2, the power supply module 4 and the input/output module 5; the power module 4 is also connected with the frequency-parameter local oscillator module 2, and the frequency-parameter local oscillator module 2 is connected with the radio-frequency front-end module 3; the radio frequency front end module 3 is used for receiving or sending radio signals; the frequency parameter local oscillator module 2 is configured to provide a frequency mixing signal for the radio frequency front end module 3, and the signal processing module 1 is configured to control operations of the modules and analyze and process a signal transmitted from the radio frequency front end module 3.

The frequency parameter local oscillator module 2 comprises a power supply processing module, a control module, a crystal oscillator frequency division module, a dot frequency synthesis module and a broadband generation module; the crystal oscillator frequency division module is respectively connected with the power supply processing module, the control module, the dot frequency synthesis module and the broadband generation module; the power supply processing module is used for providing power supply for the radio frequency local oscillation circuit; the control module is used for controlling the radio frequency local oscillation circuit to generate a proper local oscillation signal; the crystal oscillator frequency division module is used for generating a reference signal; the dot frequency synthesis module is used for synthesizing and outputting dot frequency signals; the broadband generation module is used for generating and outputting a broadband signal.

Furthermore, the crystal oscillator frequency division module comprises a DAC tuning voltage module, a crystal oscillator and two clock buffer circuits connected in parallel, wherein the DAC tuning voltage module, the crystal oscillator and the two clock buffer circuits are sequentially connected.

Further, the crystal oscillator generates an 80MHz reference signal.

Further, the dot frequency synthesis module includes an 1520MHz dot frequency local oscillator output circuit and a 1600MHz dot frequency local oscillator output circuit.

Furthermore, the 1520MHz dot-frequency local oscillator output circuit includes a first frequency synthesis chip, a first passive loop filter circuit, a first voltage-controlled oscillator, a first power divider, a first low-pass filter, a second low-pass filter, and a first amplifier; the first frequency synthesis chip is connected with the crystal oscillator frequency division module and receives a reference signal, and is connected with the first passive loop filter circuit, the first voltage-controlled oscillator and the first power divider end to form a phase-locked loop; the first power divider is further connected with the first low-pass filter, the second low-pass filter and the first amplifier in sequence to form an output circuit.

Further, the 1600MHz dot-frequency local oscillator output circuit includes a second frequency synthesis chip, a second passive loop filter circuit, a second voltage-controlled oscillator, a second power divider, a third low-pass filter, and a second amplifier; the second frequency synthesis chip is connected with the crystal oscillator frequency division module and receives a reference signal, and is connected with the second passive loop filter circuit, the second voltage-controlled oscillator and the second power divider end to form a phase-locked loop; and the second power divider is also sequentially connected with the third low-pass filter and the second amplifier to form an output circuit.

Further, the broadband generation module includes a 1691MHz-2991MHz broadband local oscillator output circuit and an 1690.7MHz-2990.7MHz broadband local oscillator output circuit.

Further, the 1691MHz-2991MHz wide-frequency local oscillator output circuit comprises a third frequency synthesis chip, a third passive loop filter circuit, a fourth low-pass filter, a third amplifier, a first pi-type attenuation network and a high-pass filter circuit; the third frequency synthesis chip is connected with the crystal oscillator frequency division module and receives a reference signal, and the third frequency synthesis chip and the third passive filter circuit form a phase-locked loop circuit; meanwhile, the third frequency synthesis chip is also sequentially connected with the fourth low-pass filter, the third amplifier, the first pi-type attenuation network and the high-pass filter circuit and outputs 1691MHz-2991MHz broadband local oscillation signals.

Furthermore, the 1690.7MHz-2990.7MHz broadband local oscillator output circuit comprises a fourth frequency synthesis chip, a fourth passive loop filter circuit, a fifth low-pass filter, a fourth amplifier, a second pi-type attenuation network and a high-pass filter circuit; the fourth frequency synthesis chip is connected with the crystal oscillator frequency division module and receives a reference signal, and the fourth frequency synthesis chip and the fourth passive filter circuit form a phase-locked loop circuit; meanwhile, the fourth frequency synthesis chip is also sequentially connected with the fifth low-pass filter, the fourth amplifier, the second pi-type attenuation network and the high-pass filter circuit and outputs 1690.7MHz-2990.7MHz broadband local oscillation signals.

Further, the comprehensive tester further comprises a communication module 6, wherein the communication module 6 is connected with the signal processing module 1 and is used for communicating the comprehensive tester with the outside.

Further, the input/output module 5 includes an input module 51 and an output module 52, wherein the input module 51 is a keyboard; the output module 52 is a liquid crystal display.

The rf front-end module 3 is provided with an antenna port (Ant port) 321, a T/R port 311, and a standing wave port (Swr port) 331.

Further, the radio frequency front end module 3 includes a T/R input/output module, an antenna input/output module, and a standing wave input/output module; the T/R input/output module adopts a T/R port 311 to carry out radio frequency input/output; the antenna input/output module adopts an antenna port 321 to perform radio frequency input/output; the standing wave input and output module adopts a standing wave port 331 to carry out standing wave input and output; the three modules are switched by a switch.

Further, the T/R input/output module comprises a T/R input module and a T/R output module, wherein,

the T/R input module includes a T/R port 311, an attenuator 312, a power divider 313, a power monitoring circuit 314, a front-end conditioning circuit 315, a down-conversion circuit 316, and an intermediate frequency conditioning circuit 317; the T/R port 311 is connected to the input end of the power divider 313 through the attenuator 312, one output end of the power divider 313 is connected to the power monitoring circuit 314, and meanwhile, the other output end of the power divider 313 is sequentially connected to the front-end conditioning circuit 315, the down-conversion circuit 316, and the intermediate-frequency conditioning circuit 317;

the T/R output module comprises a frequency synthesizer (DDS) 341, a calibration circuit 342, a frequency conversion filter circuit 343, an amplitude control circuit 344, a power divider 313, an attenuator 312 and a T/R port 311 which are connected in sequence;

the T/R port 311, the attenuator 312, and the power divider 313 in the T/R input module and the T/R output module are shared.

Further, the antenna input/output module comprises an antenna input module and an antenna output module; wherein,

the antenna input module comprises an antenna port 321, a first directional coupler 322, a front-end conditioning circuit 315, a down-conversion circuit 316 and an intermediate-frequency conditioning circuit 317 which are connected in sequence;

the antenna output module includes a frequency synthesizer (DDS) 341 (in some embodiments, the frequency synthesizer may also be integrated in the data processing module), a calibration circuit 342, a frequency conversion filter circuit 343, an amplitude control circuit 344, a first directional coupler 322, and an antenna port 321, which are connected in sequence;

the antenna port 321 and the first directional coupler 322 in the antenna input module and the antenna output module are shared, and a high-power protection circuit 323 is connected in parallel between the antenna port 321 and the first directional coupler 322.

Further, the standing wave input and output module comprises a standing wave input module and a standing wave output module; wherein,

the standing wave output module comprises a frequency synthesizer 341, a calibration circuit 342, a frequency conversion filter circuit 343, an amplitude control circuit 344, a second directional coupler 332 and a standing wave port 331 which are connected in sequence;

the standing wave input module comprises a standing wave port 331, a second directional coupler 332 and a logarithmic detector 333 which are connected in sequence; the logarithmic detector is simultaneously connected with the amplitude difference monitoring module 334 and the phase difference monitoring module 335;

the standing wave output module and the standing wave input module share a standing wave port 331 and a second directional coupler 332, and a reverse power protection circuit 336 is connected in parallel between the standing wave port 331 and the second directional coupler 332.

The power supply module includes a switching power supply 41; the switch power supply is connected with the battery 42 and the adapter 43 at the same time and is used for controlling the on-off of the power supply of the comprehensive tester; the battery 42 is used for supplying power to the comprehensive tester through the battery, and the adapter 43 is used for electrifying the comprehensive tester through 220V commercial power.

The comprehensive tester also comprises an audio generation module 7 and an audio measurement module 8;

the audio generating module 7 is connected with the signal processing module 1, and is used for generating and outputting audio with a set frequency; the audio generation module 7 is composed of a chip audio DDS chip; the two-stage digital audio synthesizer are respectively used as an audio generator I and an audio generator II, and the audio DDS chip is controlled by the SPI interface of the signal processing module 1 to synthesize output signals with corresponding frequencies.

The audio measuring module 8 is connected with the signal processing module 1 and is used for sampling and analyzing the received audio signal. The audio measuring module 8 is connected to the signal processing module 1 through an EMIF bus, and after completing sampling of the received external audio signal by AD, the audio measuring module enters a multifunctional processing unit for analysis and processing, and a display module 52 outputs corresponding measurement parameters and waveforms.

The utility model discloses total 6 types of basic test pattern and a system setup mode: the 7-class basic measurement mode is as follows: a receive test mode, a transmit test mode, a duplex test mode, an audio mode, a waveform analysis mode, a spectral analysis mode, a standing wave analysis mode.

When the transmission performance of the radio communication equipment is measured, the comprehensive tester provided by the embodiment works in a receiving mode, at this time, the comprehensive tester provided by the embodiment is equivalent to a super heterodyne radio frequency analyzer for the tested equipment, after a high-power radio frequency signal of a transmitter to be measured is input to a T/R port 311, the high-power radio frequency signal enters a power divider 313 through an attenuator 312 (in the embodiment, a 20dB/30W high-power attenuator), and one output signal of the power divider 313 enters a power monitoring circuit 314 to obtain the power of the radio frequency signal; the other output signal of the power divider 313 passes through the front-end conditioning circuit 315, the down-conversion circuit 316 and the intermediate-frequency conditioning circuit 317 in sequence and then enters the signal processing module 1.

If the instrument is set as an "antenna input port", the signal is received through the antenna port 321 after switching through the switch, and the received signal enters the signal processing module 1 after passing through the first directional coupler 322, the front-end conditioning circuit 315 (performing amplitude conditioning and mixing with the three-level local oscillation signal provided by the frequency-parameter local oscillation module), the down-conversion circuit 316 and the intermediate-frequency conditioning circuit 317 in sequence; the signal processing module 1 performs digital down-conversion on the signal, performs digital intermediate frequency sampling on the signal, sends the sampling data to a random access memory inside the signal processing module 1, and meanwhile, the digital signal processing module 1 completes analysis processing of the signal.

The integrated tester apparatus provided in the present embodiment is in a transmission mode when the reception performance of the radio communication equipment is measured. At this time, the hand-held radio comprehensive tester is equivalent to a radio frequency synthesis source for the tested device. Firstly, an intermediate frequency signal with an AM/FM function is generated by utilizing a DDS technology in a signal processing module 1, and is mixed with a plurality of local oscillation signals from a frequency reference local oscillation module 2 in a radio frequency front-end module 3 to obtain a frequency signal of 2 MHz-1300 MHz meeting the frequency range test requirement of a receiver. After the signal is amplified, filtered and attenuated, a radio frequency carrier meeting the performance test requirement of a receiver is output (the signal can be transmitted by a T/R port or an antenna port).

When the standing-wave ratio and cable test is carried out, the output signal of the frequency synthesizer in the instrument enters the directional coupler to reach the standing-wave ratio test connector (a logarithmic detector. The forward and reverse voltages on the connector are obtained by the directional coupler. After the signal is detected and amplified by a logarithmic detector, the standing-wave ratio of the device to be detected and the loss condition of the cable are obtained by software calculation, and the fault of the cable is positioned.

The audio analysis part is composed of an audio input filter, a digital oscilloscope, an audio counter and a distortion signal meter part which are contained in the signal processing module, and the analysis processing of the audio signal is completed. In the audio synthesis part, two paths of audio signals are generated by using a DDS in the signal processing board, and are output externally through an audio distribution circuit (an audio output module in an output module).

When the duplex performance of the radio communication equipment is measured, the radio frequency synthesis source and the radio frequency analyzer in the instrument work simultaneously to complete the receiver performance test and the transmitter performance test of the tested equipment, thereby realizing the radio frequency duplex measurement function. And simultaneously, the characteristics of the transmitting power, the transmitting frequency, the modulation parameter of a transmitter in the communication equipment, the receiving sensitivity, the frequency receiving selection capability, the audio output and the like of a receiver are obtained.

The embodiments of the present invention are not limited to the above embodiments, and various changes made without departing from the spirit and scope of the present invention belong to the protection scope of the present invention.

Claims (10)

1. A hand-held radio comprehensive tester is characterized in that: the system comprises a signal processing module, a radio frequency front-end module, a frequency parameter local oscillator module, a power supply module and an input/output module; the signal processing module is simultaneously connected with the radio frequency front-end module, the frequency parameter local oscillator module, the power supply module and the input/output module; the power supply module is also connected with the frequency-parameter local oscillator module, and the frequency-parameter local oscillator module is connected with the radio-frequency front-end module; the radio frequency front end module is used for receiving or transmitting radio signals; the frequency parameter local oscillator module is used for providing a frequency mixing signal for the radio frequency front end module, and the signal processing module is used for controlling the operation of each module and analyzing and processing the signal transmitted by the radio frequency front end module.

2. The hand-held radio integrated test meter of claim 1 further comprising a communication module connected to the signal processing module for communication of the integrated test meter with the outside world.

3. The hand-held radio integrated test meter of claim 1 wherein the input and output module comprises an input module and an output module, wherein the input module is a keyboard; the output module is a display.

4. The hand-held radio integrated test meter of claim 1 wherein the radio frequency front end module is provided with an antenna port, a T/R port and a standing wave port.

5. The hand-held radio integrated test instrument of claim 4, wherein the radio frequency front end module comprises a T/R input/output module, an antenna input/output module, a standing wave input/output module; the T/R input/output module adopts a T/R port to carry out radio frequency input/output; the antenna input and output module adopts an antenna port to carry out radio frequency input and output; and the standing wave input and output module adopts a standing wave port to carry out standing wave input and output.

6. The hand-held radio integrated test meter of claim 5 wherein the T/R input output module comprises a T/R input module and a T/R output module, wherein,

the T/R input module comprises a T/R port, an attenuator, a power divider, a power monitoring circuit, a front-end conditioning circuit, a down-conversion circuit and an intermediate-frequency conditioning circuit; the T/R port is connected with the input end of the power divider through the attenuator, one output end of the power divider is connected with the power monitoring circuit, and meanwhile, the other output end of the power divider is sequentially connected with the front-end conditioning circuit, the down-conversion circuit and the intermediate-frequency conditioning circuit;

the T/R output module comprises a frequency synthesizer, a calibration circuit, a frequency conversion filter circuit, an amplitude control circuit, a power divider, an attenuator and a T/R port which are connected in sequence;

and the T/R port, the attenuator and the power divider in the T/R input module and the T/R output module are shared.

7. The hand-held radio integrated test meter of claim 5 wherein the antenna input output module comprises an antenna input module and an antenna output module; wherein,

the antenna input module comprises an antenna port, a directional coupler, a front end conditioning circuit, a down-conversion circuit and an intermediate frequency conditioning circuit which are sequentially connected;

the antenna output module comprises a frequency synthesizer, a calibration circuit, a frequency conversion filter circuit, an amplitude control circuit, a first directional coupler and an antenna port which are connected in sequence;

the antenna port and the first directional coupler in the antenna input module and the antenna output module are shared, and meanwhile, a high-power protection circuit is connected between the antenna port and the first directional coupler in parallel.

8. The hand-held radio integrated test meter of claim 5 wherein the standing wave input output module comprises a standing wave input module and a standing wave output module; wherein,

the standing wave output module comprises a frequency synthesizer, a calibration circuit, a variable frequency filter circuit, an amplitude control circuit, a second directional coupler and a standing wave port which are connected in sequence;

the standing wave input module comprises a standing wave port, a second directional coupler and a logarithmic detector which are sequentially connected; the logarithmic detector is simultaneously connected with the amplitude difference monitoring module and the phase difference monitoring module;

the standing wave output module and the standing wave input module share a standing wave port and a second directional coupler, and a reverse power protection circuit is connected between the standing wave port and the second directional coupler in parallel.

9. The hand-held radio integrated test meter of claim 1 wherein the power module comprises a switching power supply; the switch power supply is connected with the battery and the adapter at the same time and is used for controlling the on-off of the power supply of the comprehensive tester.

10. The hand-held radio comprehensive tester of claim 1, further comprising an audio generation module and an audio measurement module;

the audio generation module is connected with the signal processing module and used for generating audio with set frequency and outputting the audio

The audio measuring module is connected with the signal processing module and is used for sampling and analyzing the received audio signals.