JP2508226B2 - Signal generator - Google Patents

Description

Detailed Description of the Invention [Industrial applications]

The present invention relates to a signal generator suitable as a device for generating a waveform signal for measurement, for example.

[Prior art]

For example, when measuring the performance of communication equipment, as shown in FIG. 2, from the signal generator 10, for example, a sine wave signal,
A measurement waveform signal SA such as a rectangular wave signal or a triangular wave signal is supplied to the measurement target device 11. Then, the waveform signal that has passed through the measurement target device 11 is supplied to the measuring device 12 such as a storage scope for waveform observation. The measuring device 12 samples the waveform signal that has passed through the measurement target device 11, converts the sampled value into a digital signal, processes the digital signal, and displays the measured waveform. In this case, if the signal from the measurement target device is sampled with a sampling pulse that is asynchronous with the waveform signal SA, the measured waveform cannot be observed as a static waveform. Therefore, the sampling pulse of the waveform signal needs to be synchronized with the repetition period of the waveform signal. Conventionally, a pulse PA having a repetition frequency of the waveform signal is obtained from the signal generator 10 in synchronization with the output waveform signal, and the pulse PA is supplied to the measuring device 12. The measuring device 12 forms a sampling pulse from this pulse PA.
When so-called real-time sampling is performed by the measuring device, when the number of samples per cycle of the waveform signal is 1024, for example, a sampling pulse having a frequency of 1024 times the repetition frequency of the waveform signal is required. Therefore, the measuring device multiplies the pulse PA to form a sampling pulse. Here, in the signal generator 10, generally, the repetition frequency of the output waveform signal can be changed. For this reason,
The measuring device 12 does not know what kind of repetition frequency waveform signal is input. Therefore, the measuring device 12 measures the period of the pulse PA from the signal generating device 10 to detect the frequency of the waveform signal, and multiplies the detected frequency to form a sampling pulse for real-time sampling.

[Problems to be Solved by the Invention]

As described above, conventionally, since the sampling pulse of the signal that has passed through the measurement target device is formed by the measuring device, it is necessary to measure the frequency of the pulse synchronized with the waveform signal from the signal generating device. Was complicated. Further, in the real-time sampling, the processing speed of the measuring device needs to be high when the frequency of the waveform signal is high, and an expensive measuring device has been required. Equivalent sampling methods and multiple sampling methods are known as sampling methods suitable for processing at a lower speed than before. The equivalent sampling method is such that one sample is sampled every one to a plurality of cycles of the waveform signal and the sampling point is shifted every sample. Therefore, the time to obtain data per waveform is
It takes a time (several times the number of samples for one waveform) as compared with the real-time sampling, and the processing speed may be slow. In the multiple sampling method, a plurality of waveforms of one cycle are sampled and the sampling position is shifted by the waveform of each cycle, and the processing speed may be intermediate between the real time sampling method and the equivalent sampling method. If the measuring apparatus can adopt the sampling method as described above, the measuring apparatus having a low processing speed can measure even if the frequency of the waveform signal is high. However, when such a low-speed sampling method is adopted, the processing time becomes very long when the frequency of the measurement waveform signal is low. It is conceivable that the measuring device is provided with sampling signal generating means corresponding to the above three kinds of sampling methods, and the sampling signal generating means is switched according to the processing speed. However, in that case, the structure of the measuring device is complicated. And the cost increases. An object of the present invention is to provide a signal generator capable of improving the above drawbacks.

[Means for Solving the Problems]

A signal generator according to the present invention comprises a waveform signal generator for generating a signal of a predetermined waveform having a variable repetition frequency, means for obtaining a pulse of the repetition frequency of the waveform signal from the waveform signal generator, and dividing the pulse. A first variable frequency dividing circuit, a variable frequency oscillator, a second variable frequency dividing circuit that divides the output signal of the variable frequency oscillator, and output signals of the first and second frequency dividing circuits. A phase comparison circuit for phase comparison, a control means for generating a signal for determining a repetition frequency of the waveform signal from the waveform signal generator, and a signal for determining a frequency division ratio of the first and second variable frequency division circuits. And a waveform signal of the set frequency is obtained from the waveform signal generator, and the oscillation frequency of the variable frequency oscillator is controlled based on the output of the phase comparison circuit. So that the clock pulses from the frequency oscillator is synchronized with the waveform signal is obtained.

[Action]

From the signal generator according to the present invention, the waveform signal having the frequency set by the signal from the control means can be obtained, and the clock pulse synchronized with the waveform signal can be obtained. This clock pulse can have various frequencies by appropriately setting the frequency division ratios of the first and second variable frequency dividing circuits by a signal from the control means. Therefore, when the signal generator of the present invention is used in the above-mentioned measuring signal generator, the output waveform signal is used together with the sampling clock for real-time sampling, the sampling clock for equivalent sampling, and the sampling clock for multiple sampling. Either can be easily obtained selectively.

【Example】

An embodiment of the present invention will be described below with reference to FIG. 21 is a waveform signal generator, for example, a sine wave,
A rectangular-wave or triangular-wave waveform signal SA is selectively obtained, and its output waveform signal is led to the output terminal 20. The frequency of the waveform signal SA which is the output signal of the waveform signal generator 21 is variable. This can be achieved, for example, by providing a variable frequency oscillator and a frequency dividing circuit and changing the frequency dividing ratio of the frequency dividing circuit. 22 is a computer such as a microcomputer (hereinafter referred to as CPU). The CPU 22 is supplied with a signal from an input means 23 including a select button and the like.
Then, in response to the operation of the select button or the like of the input means 23, a waveform selection signal is supplied from the CPU 22 to the waveform signal generator 21, and a signal for determining the repetition frequency f of the output waveform signal SA, for example, A signal for setting the frequency division ratio of the frequency dividing circuit provided in the waveform signal generator 21 is supplied. The waveform signal SA from the waveform signal generator 21 is also supplied to the forming means 24 of the pulse PI having the repetition frequency of this waveform signal. The forming means 24 can be composed of, for example, a level comparison circuit, and by comparing the waveform signal SA with a zero level to detect the zero cross of the waveform signal, the pulse PI of the repetition frequency f of the waveform signal SA can be obtained. This pulse PI is supplied to the first variable frequency dividing circuit 25. The dividing ratio 1 / K of the dividing circuit 25 is given from the CPU 22. The output signal of the frequency divider circuit 25 is supplied to one input terminal of the phase comparison circuit 26. 27 is a variable frequency oscillator (hereinafter referred to as VCO).
The oscillation output of 27 is supplied to the second frequency dividing circuit 28. The dividing ratio 1 / S of the dividing circuit 28 is also given from the CPU 22.
The output signal of the frequency divider circuit 28 is supplied to the other input terminal of the phase comparison circuit 26. In the phase comparison circuit 26, the first and second frequency dividing circuits 25 and
The output signal from 28 is phase-compared, and the phase-comparison error output is supplied to VCO 27 via low-pass filter 29, the oscillation frequency of this VCO 27 is controlled, and the clock pulse SP that is the output signal of this VCO 27 generates a waveform signal. It is made to synchronize with the output waveform signal SA of the device 21. This clock pulse SP
Are led to the output terminal 30. When the signal generator of FIG. 1 is used as the measuring signal generator described above, the waveform signal SA obtained at the output terminal 20 is supplied to the device under measurement. Further, the clock pulse SP obtained at the output terminal 30 is supplied to the input terminal of the sampling signal of the measuring device. In this case, the measuring device does not require a sampling signal forming circuit. The frequency fs of the output signal SP of the VCO 27 is determined by the frequency f of the waveform signal and the frequency division ratio of the frequency dividing circuits 25 and 28. Now, set the number of waveforms to be sampled by N (=
1/2 ⁿ , or = 0; n is a positive integer), and when the number of sampling data per cycle is M (= 2 ^m ; m is a positive integer), It is expressed as The frequency division ratio of the first and second frequency dividing circuits 25 and 28 is S =
It is set as M and K = MN + 1. Here, if N = 0, fs = S × f, and the output clock pulse SP becomes a sampling pulse for real-time sampling. If 0 <N <1, the output clock pulse SP
Is a sampling pulse for multiple sampling. Further, if N1, the output clock pulse SP is
It becomes a sampling pulse of equivalent sampling. In this case, the value of M is set according to the number of sample data per cycle of the waveform signal in the measuring device. Therefore, in this example, the input means 23 is provided with means for setting the value of M so that the value of M can be set appropriately. When the number of sampled data per cycle in the measuring device is a predetermined plural number, this M
The means for setting the value of may be a means for selecting a plurality of sample data numbers. However, if the number of sample data per cycle is fixed in the measuring device, the value of M may be stored in the CPU 22 in advance, and the means for setting the value of M may not be provided. Similarly, the input means 23 is provided with means for setting the value of N, whereby the value of N can be set appropriately. Further, instead of providing the setting means for setting the value of N, the input means 23 is provided with a selecting means for selecting one of real-time sampling, multiple sampling and equivalent sampling, and the selecting method is selected depending on the sampling method selected by the selecting means. The value of N can be set by the CPU 22. In that case, the value of N may be set to a desired value during the equivalent sampling and the multiple sampling. Further, without providing a setting means or a selecting means for the value of N,
The value of N may be automatically set in the CPU 22 in accordance with the repetition frequency of the output waveform signal determined by the signal from the CPU 22. That is, for example, the value of N is set so that the output clock pulse SP becomes a sampling pulse for equivalent sampling when the waveform signal SA has a high frequency, and the output clock pulse SP is real when the waveform signal SA has a low frequency. The value is set to be a sampling pulse for sampling, and when the waveform signal SA has an intermediate frequency, the output clock pulse SP is a sampling pulse for multiple sampling. By doing so, even a measuring device having a relatively low processing speed can efficiently perform measurement from a high frequency to a low frequency of the measurement signal. In the above, the case where the signal generator according to the present invention is used as a generator for a measurement signal has been described as an example, but it goes without saying that the signal generator according to the present invention can be used for various other purposes. Nor.

【The invention's effect】

As described above, according to the present invention, together with the waveform signal,
A clock pulse synchronized with this waveform signal can be obtained. Moreover, the frequency of this clock pulse can be changed by changing the frequency division ratio of the first and second variable frequency dividing circuits. Therefore, when the clock pulse is used as the sampling pulse of the output waveform signal, the frequency of the clock pulse can be easily selected according to the sampling method of the output waveform signal. In particular, when the signal generator of the present invention is used as a measuring signal generator, real-time sampling of clock pulses, multiple sampling, The pulse can be a pulse corresponding to each sampling method of equivalent sampling. Further, when the measuring device has a relatively slow processing speed, by setting the division ratio of the first and second variable frequency dividing circuits according to the frequency of the output waveform signal, the measurement waveform signal Efficient measurement can be performed over a wide frequency range.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention, and FIG. 2 is a diagram for explaining an example of a measurement system of a usage example of the present invention. 20; Waveform signal output terminal 21; Waveform signal generator 22; CPU 24; Means for forming pulse PI of repetition frequency of waveform signal 25; First frequency dividing circuit 26; Phase comparison circuit 27; VCO 28; Second Divider circuit 30; Clock pulse output terminal

Claims (2)

(57) [Claims] 1. A measuring apparatus capable of using a real-time sampling method, an equivalent sampling method, and a multi-sampling method as a sampling method for an input signal, while generating a waveform signal to be supplied through a device under test and at the same time A waveform generator that generates a clock pulse that is synchronized with the waveform signal and that is used for sampling the waveform signal in the measuring device, the waveform signal generator generating the waveform signal having a variable repetition frequency; Means for obtaining a pulse having a repetition frequency of the waveform signal from the waveform signal generator, and a first frequency divider for dividing a pulse having a repetition frequency of the waveform signal
, A variable frequency oscillator, a second variable frequency divider that divides the output signal of the variable frequency oscillator, and a phase comparison of the output signals of the first and second variable frequency dividers. A phase comparison circuit that outputs the comparison error signal as a signal for controlling the oscillation frequency of the variable frequency oscillator; a waveform signal output terminal that outputs the waveform signal from the waveform signal generator; A pulse output terminal for outputting the output signal as the clock pulse, input means for specifying the repetition frequency of the waveform signal from the waveform signal generator, and a signal for specifying the frequency of the waveform signal from the input means. The waveform signal generator is supplied with a signal for controlling the frequency of the waveform signal to the specified frequency, and the repetition frequency of the waveform signal is changed. Accordingly, the frequency division of the first variable frequency dividing circuit is performed based on the number of data per cycle of the waveform signal required by the measuring device and the number of waveforms of each waveform of the waveform signal to be sampled. Generating a signal defining a ratio and a dividing ratio of the second variable divider circuit,
When the repetition frequency is high, the clock pulse for sampling the waveform signal by the equivalent sampling method is repeated, and when the repetition frequency is low, the clock pulse for sampling the waveform signal by the real-time sampling method is repeated. When the frequency is between the high frequency and the low frequency,
And a control means for outputting clock pulses for sampling by the multiple sampling method from the pulse output terminals, respectively. 2. A measuring apparatus capable of using a real-time sampling method, an equivalent sampling method, and a multi-sampling method as a sampling method for an input signal, while generating a waveform signal to be supplied through a device to be measured, A signal generator that generates a clock pulse for sampling the waveform signal in the measuring device in synchronization with the waveform signal, the waveform signal generator generating the waveform signal having a predetermined repetition frequency, A means for obtaining a pulse having a repetition frequency of the waveform signal from the waveform signal generator; and a first frequency divider for dividing a pulse having a repetition frequency of the waveform signal.
, A variable frequency oscillator, a second variable frequency divider that divides the output signal of the variable frequency oscillator, and a phase comparison of the output signals of the first and second variable frequency dividers. A phase comparison circuit that outputs the comparison error signal as a signal for controlling the oscillation frequency of the variable frequency oscillator; a waveform signal output terminal that outputs the waveform signal from the waveform signal generator; A pulse output terminal for outputting the output signal of as the clock pulse, and as the clock pulse from the pulse output terminal,
Input means for designating to output a clock pulse according to the sampling method adopted in the measuring device; and a signal from the input means for receiving a signal from the input device per cycle of the waveform signal. Generating a signal that determines the frequency division ratio of the first variable frequency division circuit and the frequency division ratio of the second variable frequency division circuit from the number of data and the number of waveforms of each waveform of the waveform signal to be sampled. And a control means for controlling the signal generation device.