JP2019129333A - Signal generator and output level adjustment method thereof - Google Patents

Abstract

To provide a signal generator capable of adjusting a signal condition at an output end of an external module, even if a connection condition of connection means for providing connection between a main unit and the external module changes.SOLUTION: A signal generator 1 includes: a main unit 2 for generating an arbitrary signal; and an external module 3, connected to the main unit 2 with a signal cable 4 and a control cable, for converting frequency of a signal generated at the main unit 2 to which an input is provided with the signal cable 4 and for outputting the converted signal. The external module 3 includes: a mixer 32 for converting frequency of a signal generated at the main unit 2; and a variable attenuator 31 arranged at pre-stage of the mixer 32. The main unit 2 includes a controller 23 for performing coarse adjustment by the variable attenuator 31 when an output signal level of the external module 3 is adjusted.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a signal generator for generating a modulation wave in a desired frequency band.

  As a signal generator for generating a modulation wave of a desired frequency band, for example, a signal generator for converting a frequency of an intermediate frequency signal generated by an arbitrary signal generator with a mixer or the like to generate a modulation wave of a desired frequency band Are known.

  Such a signal generator is incorporated in, for example, a mobile terminal test apparatus that tests a mobile communication terminal, and generates and outputs a test signal.

  In Patent Document 1, a test signal generator and a transmission antenna and a MIMO (Multiple Input Multiple Output) communication device arranged inside an anechoic chamber are connected by a cable, and the MIMO communication device is arranged in an anechoic chamber for testing. It is disclosed to do.

  In the configuration of the measurement system disclosed in Patent Document 1, the cable connected to the test signal generator is drawn into the anechoic chamber, and the drawn cable is connected to the transmission antenna disposed inside the anechoic chamber. The signal of the test signal generator is output to the MIMO communication apparatus in the radio anechoic chamber through the transmission antenna.

  As a configuration similar to this measurement system, instead of directly connecting the test signal generator and the transmitting antenna located inside the anechoic chamber with a cable, some functions of the test signal generator are located in the immediate vicinity of the anechoic chamber. Other functions of the test signal generator that is located away from the anechoic chamber are connected to the transmitting antenna arranged inside the anechoic chamber and the external module. In some cases, a device (device main body) having the above and an external module are connected by a cable.

International Publication No. 2012/108124

  However, when the main unit and external module are connected by cables in this way, the cable length etc. will change if there is an exchange of cables due to movement of the installation place of the radio anechoic chamber and the external module and the main unit. If the cable loss changes, the signal level at the output end of the external module, SNR (Signal-Noise Ratio), distortion characteristics and other conditions (transmission characteristics) change, and there is a problem that numerical compensation cannot be performed. The

  Therefore, an object of the present invention is to provide a signal generator capable of adjusting the signal condition at the output end of the external module even if the connection condition of the connection means for connecting the main unit and the external module changes. .

  The signal generating apparatus according to the present invention is connected to the main body by a main body generating an arbitrary signal and a connecting means whose transmission characteristics are changed by exchange, and is generated at the main body being input through the connecting means An external module that frequency-converts the received signal by the mixer and outputs the external signal, the external module including a variable attenuator at the front stage of the mixer, and the main unit includes an output of the external module When the signal level is adjusted, a control unit is provided for performing rough adjustment by the variable attenuator.

  With this configuration, coarse adjustment is performed by the variable attenuator at the front stage of the mixer. Therefore, even if the connection condition of the connection means for connecting the main unit and the external module changes, the signal condition at the output end of the external module can be adjusted.

  Further, in the signal generator of the present invention, the external module includes an output level monitor unit for detecting the level of the output signal, and the control unit is configured to execute the output signal level detected by the output level monitor unit. It adjusts the level of the output signal of the external module.

  With this configuration, the level of the output signal of the external module is adjusted based on the level of the output signal detected by the output level monitor unit of the external module. Therefore, the level of the output signal can be adjusted with high accuracy.

  Further, in the signal generator of the present invention, the control unit performs the fine adjustment by adjusting the level of the signal output from the main unit after the rough adjustment is performed by the variable attenuator.

  With this configuration, after the coarse adjustment is performed by the variable attenuator, the level of the signal output from the main body is adjusted and fine adjustment is performed. Therefore, the level of the output signal can be adjusted with high accuracy.

  Further, according to the output level adjusting method of the signal generating apparatus of the present invention, the signal processing apparatus is connected to the main body by a main body generating an arbitrary signal and a connecting means whose transmission characteristics are changed by replacement. An external module that frequency-converts and outputs a signal generated in the main unit by a mixer, and the external module is an output level adjusting method of a signal generating apparatus including a variable attenuator at a stage before the mixer And performing the coarse adjustment with the variable attenuator.

  With this configuration, coarse adjustment is performed by the variable attenuator at the front stage of the mixer. For this reason, even if the connection condition of the connection means for connecting the main body and the external module changes, the signal condition at the output end of the external module can be adjusted.

  The present invention can provide a signal generator capable of adjusting the signal condition at the output end of the external module even if the connection condition of the connection means for connecting the main unit and the external module changes.

FIG. 1 is a block diagram of a signal generator according to an embodiment of the present invention. FIG. 2 is a flowchart for explaining the procedure of level adjustment processing of the signal generator according to the embodiment of the present invention.

  Hereinafter, a signal generation device according to an embodiment of the present invention will be described in detail with reference to the drawings.

  In FIG. 1, a signal generator 1 according to an embodiment of the present invention includes a main unit 2 that generates an intermediate frequency band signal, and a signal of a predetermined frequency band that is an intermediate frequency band signal generated by the main unit 2. And an external module 3 for frequency conversion. The main body 2 and the external module 3 are connected by a signal cable 4 and a control cable 5. The signal cable 4 transmits an intermediate frequency band signal generated by the main body 2. The control cable 5 transmits a signal for the control unit 23 of the main unit 2 to control each unit of the external module 3, a signal for each unit of the external module 3 to notify information to the control unit 23 of the main unit 2, and the like. .

  The signal cable 4 and the control cable 5 are exchangeable according to, for example, the installation positions of the main body 2 and the external module 3.

  The main body 2 includes an arbitrary signal generator (AWG: Arbitrary Waveform Generator) 21, an operation unit 22, and a control unit 23.

  The arbitrary signal generator 21 generates an arbitrary pattern of signals. The arbitrary signal generator 21 is configured by a DAC (Digital to Analog Converter), an FPGA (Field-Programmable Gate Array), or the like.

  The operation unit 22 includes input devices such as a keyboard, a mouse, and a touch panel, and outputs setting information of a generated signal that has been operated and input to the control unit 23.

  The control unit 23 is configured by, for example, a computer device. The computer device includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a non-volatile storage medium such as a hard disk device, and various input / output ports. .

  The ROM and the hard disk device of this computer device store a program for causing the computer device to function as the control unit 23. That is, when the CPU executes a program stored in the ROM with the RAM as a work area, the computer device functions as the control unit 23.

  The control unit 23 causes the arbitrary signal generator 21 to generate a signal based on the setting information of the generation signal input to the operation unit 22, and controls each unit of the external module 3 described later to conform to the setting information of the generation signal. Output a signal.

  The external module 3 includes a variable attenuator 31 that adjusts the level of the signal input from the main body 2, a mixer 32 that converts the signal level adjusted by the variable attenuator 31 to a predetermined frequency band, and a mixer 32. A local oscillator 33 that generates a local oscillation signal for frequency conversion, an amplifier 34 that amplifies the signal mixed by the mixer 32, a variable attenuator 35 that adjusts the level of the signal amplified by the amplifier 34, and a variable attenuator 35 And an output level monitor 37 for detecting the level of the signal whose level is adjusted by the variable attenuator 35.

  The adjustment amount of the variable attenuator 31 and the variable attenuator 35, the frequency of the local oscillation signal generated by the local oscillator 33, the amplification amount by the amplifier 34, etc. are determined via the control cable 5 from the control unit 23 of the main unit 2. Controlled by the signal. The information detected by the output level monitoring unit 37 is transmitted to the control unit 23 of the main unit 2 via the control cable 5.

  In the signal generator 1 having such a configuration, the performance deterioration (the SNR deterioration or the distortion characteristic deterioration) in the mixer 32 is likely to occur. For this reason, it is desired to reduce performance deterioration in the mixer block stage as much as possible.

  Not only the mixer but also many semiconductor components must consider the coexistence of distortion characteristics and NF (Noise Figure) characteristics. In the case of a mixer, it is important to set the mixer input level to an appropriate value. The value should be as high as possible in consideration of the SNR, but if it is too high, distortion will occur in the mixer stage, and the level will be as high as possible in the range where there is no problem with distortion characteristics.

  In the case of the signal generator 1 of the present embodiment, the goal is to bring the signal to the final output stage so as to minimize the SNR of the output stage of the optional signal generator 21 as much as possible. If only the SNR is not deteriorated, a low NF amplifier may be arranged at the output stage of the arbitrary signal generator 21 to obtain a gain.

  However, in a measuring instrument, it does not mean that only gain should be taken. This is because the semiconductor device is a non-linear element and generates a distortion component. Many measuring instruments perform waveform generation in accordance with a desired application, and the distortion component described above becomes a factor that deteriorates the quality of these waveforms.

  Therefore, the design is performed in consideration of the distortion characteristics of the parts to be used while obtaining the gain so that the SNR does not deteriorate. In particular, when a mixer is included in the block configuration, the mixer section often contributes to the SNR with respect to other blocks.

  The NF of the mixer is Conversion Loss + α, which is generally 8 to 10 dB. For this reason, the loss is larger than a simple signal path loss or a filter loss, and the block tends to be a factor of SNR deterioration. Because it is a block with a large NF, it is desirable to take gain by the previous stage, but since the mixer tends to have lower distortion performance with respect to the amplifier etc., when the level of the mixer input is increased, the distortion performance of the mixer causes a dynamic range. Getting worse.

  In many cases, the signal path is fixed, and optimization adjustment may be performed at the time of development. However, in the case of the signal generator 1 of this embodiment, the main unit 2 and the external module 3 are separated. The loss value (transmission characteristic) of the connection means (the part of the signal cable 4 in the present embodiment) in the part where the change is made changes depending on what connection means is used, and optimization does not make sense.

  In order to solve such a problem, in the present embodiment, the variable attenuator 31 is arranged in the previous stage of the mixer 32 of the external module 3, and the adjustment value of the variable attenuator 31 is changed even when the condition of the connection means is changed. Thus, the input level of the mixer 32 can be managed.

  When the level adjustment of the output frequency is requested by the operation input to the operation unit 22, the control unit 23 adjusts the set output frequency. When a plurality of frequencies are set as the output frequency, the frequency is adjusted for each. Further, when the frequency range (upper limit value and lower limit value) is set as the output frequency, the adjustment is performed at a preset frequency interval between the upper limit value and the lower limit value of the set frequency.

  The control unit 23 sets each unit to output the set frequency, and measures the difference value between the level set from the detection result of the output level monitor unit 37 and the output level.

  The control unit 23 roughly adjusts the difference between the set level and the output level by the variable attenuator 31 of the external module 3. This is because the input level of the mixer 32 is adjusted by the variable attenuator 31 in a predetermined value, for example, 1 dB. As a result, the input level of the mixer 32 is roughly adjusted in predetermined value units.

  The control unit 23 performs coarse adjustment by the variable attenuator 31 of the external module 3, and then finely adjusts the output level by adjusting the output level of the arbitrary signal generator 21, for example. The fine adjustment may be performed by providing ALC (Auto Level Control) or the like in the external module 3.

  Thus, in the process of adjusting the output level, the coarse adjustment is performed by the variable attenuator 31 of the external module 3, so that the level adjustment can be performed without greatly changing the designed level diagram.

  In the level diagram creation of the external module 3, in consideration of the fact that the loss changes to some extent due to cable loss or the like, the gain is adjusted so that the influence on the SNR is reduced even if the variable attenuator 31 of the external module 3 is adjusted. It is good to set it as taken.

  The level adjustment process by the signal generator 1 according to the present embodiment configured as described above will be described with reference to FIG. The level adjustment process described below is started when the level adjustment of the output frequency is requested by the operation input to the operation unit 22.

  In step S1, the control unit 23 sets each unit so as to output the set frequency.

  In step S2, the control unit 23 measures the difference value of the level set as the output level from the detection result of the output level monitoring unit 37.

  In step S3, the control unit 23 performs rough adjustment with the variable attenuator 31 on the difference value of the level set as the output level.

  In step S <b> 4, the control unit 23 measures again the difference value between the output level and the set level from the detection result of the output level monitoring unit 37.

  In step S5, the control unit 23 adjusts and adjusts the output level of the arbitrary signal generator 21 with respect to the output level and the remaining difference value of the set level.

  In step S <b> 6, the control unit 23 determines whether level adjustment has been performed for all frequencies to be adjusted. If it is determined that the level adjustment has not been performed for all the frequencies, the control unit 23 returns to step S1 and repeats the process.

  If it is determined in step S6 that level adjustment has been performed for all frequencies, the control unit 23 ends the process.

  While embodiments of the present invention have been disclosed, it will be apparent to one skilled in the art that modifications can be made without departing from the scope of the present invention. All such modifications and equivalents are intended to be included in the following claims.

1 signal generator 2 main unit 3 external module 4 signal cable (connection means)
5 Control Cable 21 Arbitrary Signal Generator 23 Control Unit 31 Variable Attenuator 32 Mixer 37 Output Level Monitor Unit

Claims (4)

A main unit (2) that generates an arbitrary signal;
Externally connected to the main body by connection means (4) whose transmission characteristics are changed by exchange, and the signal generated in the main body inputted via the connection means is frequency converted by the mixer (32) and output A signal generator comprising a module (3), wherein
The external module comprises a variable attenuator (31) in front of the mixer,
The said main-body part is a signal generator provided with the control part (23) which performs rough adjustment with the said variable attenuator, when adjusting the level of the output signal of the said external module. The external module includes an output level monitoring unit (37) that detects the level of the output signal;
The signal generator according to claim 1, wherein the control unit adjusts the level of the output signal of the external module based on the level of the output signal detected by the output level monitoring unit.   The signal generator according to claim 1 or 2, wherein the control unit performs the fine adjustment by adjusting the level of the signal output from the main unit after the coarse adjustment is performed by the variable attenuator. A signal generated at the main body (2) which generates an arbitrary signal and a signal which is connected to the main body by connection means (4) whose transmission characteristics are changed by replacement and which is input via the connection means An external module (3) for converting the frequency of the signal by a mixer (32) and outputting the same, and the external module is an output level adjusting method of a signal generator provided with a variable attenuator (31) at a front stage of the mixer ,
A method of power level adjustment comprising the step of performing a coarse adjustment with the variable attenuator.

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