JP2001311754A - Time measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a time measuring device capable of outputting quantitatively comparable measured values and making an optimum phase adjustment based on the indicated value of an analog meter in the measurement of the plural time differences between two signals having different clock frequencies. SOLUTION: A variable delay section 21 delays an inputted clock signal 102 based on a specified quantity from a panel operation section 26. A time difference measurement section 22 measures the time difference between a data signal 101 and the clock signal 102, converts the time difference measured value into frequency data 103 including the measured value frequency, and stores the frequency data 103 in a frequency data storage memory 27. A period measurement section 23 measures the period measured value of the clock signal 102, converts it into period data 104, and stores the period data 104 in a period data storage memory 28. An arithmetic section 24 calculates a phase difference value 105 which is the ratio of the period measured value against the time difference measured value based on the frequency data 103 and the period data 104 and inputs the phase difference value 105 to a display section 25. The display section 25 displays the angle of the phase difference value 105.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a time measuring device, and more particularly to a time measuring device suitably used for a jitter meter or a time interval analyzer for measuring a time difference between a data signal and a clock signal. .

[0002]

2. Description of the Related Art A measuring instrument for measuring time or frequency is generally called an electronic counter, and is used in various fields because of its simplicity. The time interval analyzer is a state-of-the-art time measurement device.In addition to the function of a universal counter, it stores the measured values such as time and frequency in a memory, and analyzes the jitter and frequency, which are the time fluctuations of the measured values, from many data It has a function to analyze the time change and the like and to display the analysis result on a graphic screen. The jitter meter is positioned as a lower model of the time interval analyzer, limits the functions, displays the analysis result with an analog meter or the like, and performs high-speed measurement.

FIG. 10 is a block diagram of a conventional time measuring device. The signal source 1 inputs the data signal 101 and the clock signal 102 to the time measuring device 2A. The variable delay unit 21 is controlled by a specified amount from the panel operation unit 26.
The clock signal 102 is delayed and input to the time difference measurement unit 22. The time difference measurement unit 22 performs sample measurement of the time difference between the data signal 101 and the clock signal 102 a plurality of times, and generates frequency data 103 including time difference data including a plurality of time difference measurement values and the measurement value frequency in all samples. . The time difference measurement unit 22 stores the generated frequency data 103 in the frequency data storage memory 27.

[0004] The operation unit 24 includes a frequency data storage memory 27.
The frequency data 103 is read from the data, the time difference data is averaged, and input to the display unit 25 as a time difference average value 106.
The display unit 25 displays the time difference average value 106. Also,
The measurer can also grasp the state of the measurement sample by displaying the histogram of the measurement value frequency in all the samples together with the time difference data.

[0005]

The time difference average value 106 does not include information on the clock signal 102. For this reason, the operator measures the data signal 101 and the clock signal 1
Since only an absolute evaluation can be made as to how much time difference exists between the clock signal 102 and the clock signal 102, the phase difference with respect to the clock signal 102 cannot be known. When the same measurement is performed while changing the frequency of the clock signal 102, the average time difference value 106 indicates a value different from the previous measurement according to the change in the frequency. The measurement result of 106 could not be quantitatively compared as a phase difference with respect to the clock signal 102.

A time interval analyzer is
While observing the waveform on the graphic screen, adjust the phase by taking measures such as changing the cable length. However, the jitter meter employs an analog meter display and does not have a function of observing a waveform, so that there is also a problem that an optimum phase adjustment cannot be performed only by the main body.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art. In the measurement of the time difference between two signals, each measurement is performed even when the frequency of one signal changes. It is an object of the present invention to provide a time measuring device capable of quantitatively comparing results.

[0008]

To achieve the above object, a time measuring apparatus according to the present invention comprises a time difference measuring section for sampling a time difference between rising and falling of two signals a plurality of times to generate time difference data. A period measurement unit that measures the period of one signal, and a time difference between the two signals obtained by the statistical operation based on the time difference data, and a ratio between the calculated statistical time difference and the period measured by the period measurement unit. And a calculation unit for calculating a phase angle difference between the two signals.

The time measuring apparatus of the present invention calculates a phase angle difference based on a ratio of a statistical time difference obtained by statistically processing a time difference between two signals and a cycle of a clock frequency, and displays the difference as a measurement result. In a plurality of measurements of a time difference having different frequencies, even when the frequency of one signal changes, the respective measurement results can be quantitatively compared.

The time measuring device of the present invention preferably further comprises a variable delay unit for delaying one of the two signals and inputting the delayed signal to the time difference measuring unit.
In this case, it is easy to adjust the phase.

The arithmetic unit represents the time difference data as a histogram, and calculates 1/1/3 of the period measured by the period measuring unit from the midpoint of the time difference measurement value corresponding to the histogram curve whose frequency is lower than a predetermined threshold value. It is also a preferred embodiment of the present invention to select a time difference measurement value located two positions apart as the statistical time difference. In this case, regardless of the histogram shape of the compression frequency data, the peak of the histogram shape is not broken, and the optimum time difference measurement value is selected as the representative value. Therefore, the optimum phase adjustment is performed based on the indicated value of the analog meter. Can be performed.

Further, in the time measuring device according to the present invention, the arithmetic section can select and output the most frequent measured time difference value from the time difference data.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a time measuring device according to the present invention will be described based on an embodiment of the present invention with reference to the drawings. FIG. 1 is a block diagram of a time measuring device 2 and a signal source 1 to be measured thereof according to a first embodiment of the present invention.
The time measurement device 2 includes a variable delay unit 21, a time difference measurement unit 22, a cycle measurement unit 23, a calculation unit 24, a display unit 25, a panel operation unit 26, a frequency data storage memory 27, and a cycle data storage memory 28. You.

FIG. 2 is a diagram showing a specific example of the signal source 1 of FIG. 1, showing an example of jitter measurement when a data signal fluctuates with respect to a clock signal of an optical disk. The signal source 1 processes the output signal from the optical disk 11 by the equalizer 12, and outputs the data signal 101 passed through the comparator 13 and the PLL circuit 1.
4 to the generated clock signal 102. The signal source 1 inputs the data signal 101 and the clock signal 102 to the time measuring device 2.

FIG. 3 is a flowchart showing the operation of the time measuring device 2 of FIG. The measurer operates the panel operation unit 26
To specify an arbitrary delay amount (step S1).
1). The variable delay unit 21 delays the clock signal 102 according to the delay amount specified by the panel operation unit 26,
It is input to the time difference measuring unit 22 and the period measuring unit 23. The data signal 101 is directly input to the time difference measuring unit 22.

FIG. 4 is a timing chart for explaining the time difference measurement performed by the time difference measurement unit 22. The time difference measuring unit 22 performs a plurality of time difference measurements for obtaining a time from the rising time of the data signal 101 to the next rising time of the clock signal 102 as a signal time difference. Time difference measuring unit 22, for example to create a time difference data consisting of 10 ^five samples about time difference measurements. According to the specific example shown in FIG. 2, the cycle T2 of the clock signal 102 is
Since the period of the data signal is shorter than the period T1, the measured time difference is 0.
ＴT2 [s].

FIG. 5 is a timing chart for explaining the cycle measurement performed by the cycle measuring section 23.
The cycle measuring unit 23 repeats cycle measurement a plurality of times to determine the time from the rising time of one clock pulse of the clock signal 102 to the rising time of the next clock pulse as one cycle of the clock signal 102. Period measurement unit 2
3 creates cycle data composed of cycle measurement values of a plurality of samples (step S12).

The time difference measuring section 22 converts the time difference data into frequency data 103 and stores it in the frequency data storage memory 27 (step S13). The frequency data 103 is data including time difference data and a frequency indicating the frequency of the time difference measurement value for all samples. Period measurement unit 23
Stores the cycle data 104 in the cycle data storage memory 28 (step S14).

FIG. 6 is a histogram showing a state when calculating the phase difference performed by the calculation unit 24. The frequency data 103 is represented as a normal distribution histogram as shown in FIG. Referring back to FIG.
Reads the frequency data 103 from the frequency data storage memory 27 and calculates the time difference measurement value (the most frequent time difference) with the highest measurement frequency from all the samples (step S).
15). The arithmetic unit 24 reads the cycle data 104 from the cycle data storage memory 28 and calculates a cycle measurement value from the cycle data 104 (Step S16). Arithmetic unit 24
Divides the most frequent time difference by the period measurement value to obtain a time difference standardized by the period, and then multiplies the ratio by 360 to obtain a phase angle difference between the two signals (step S17). The calculation unit 24 inputs the normalized phase difference value 105, which is the calculation result, to the display unit 25.

FIG. 7 shows an example of the display section 25 of FIG.
The display unit 25 displays the phase difference value 105 at an angle using an analog meter as shown in FIG.
Wait for setting by the operator Maintain the setting waiting state. Returning to step S11 again, the measurer operates the panel operation unit 26 according to the phase difference value 105 of the display unit 25 to adjust the phase. The phase adjustment is performed by adjusting the phase difference value 105 displayed by the display unit 25 to 180 degrees, whereby the delay amount of the variable delay unit 21 is set optimally.

According to the embodiment, the most frequent time difference between the data signal and the clock signal is normalized by the measured value of the cycle of the clock signal and is displayed as a measurement result. In the measurement, each measurement result can be quantitatively compared.

FIG. 8 is a flowchart showing the operation of the phase adjustment performed by the time measuring device according to the second embodiment of the present invention. The configuration of the time measuring device itself is the same as that shown in FIG. The arithmetic unit 24 represents the time difference data as a histogram, and calculates the period of the clock signal 102 measured by the period measuring unit 23 from the midpoint of the time difference measured value corresponding to the histogram curve whose frequency is lower than the predetermined threshold. The time difference measurement at a location separated by / 2 is selected as the statistical time difference. The present embodiment is different from the previous embodiment in that the phase angle difference is calculated using this statistical time difference instead of the most frequent time difference.

The measurer operates the panel operation unit 26 to
An arbitrary delay amount is set (step S21). The time measuring device 2 performs time difference measurement and period measurement (Step S).
22) The frequency data 103 and the cycle data 104 are stored in the frequency data storage memory 27 and the cycle data storage memory 28, respectively.

The arithmetic unit 24 reads the frequency data 103, calculates a time difference measurement value with the smallest measurement frequency (minimum frequency) from all the samples (step S23), and has a frequency less than the minimum frequency or a predetermined frequency. Time difference data,
Re-conversion is performed as compressed frequency data with the frequency set to 0 (step S24).

FIGS. 9A to 9I are histograms showing specific examples of compression frequency data. (A) to (c) of FIG.
The histogram of shows a normal distribution shape, and FIG.
The histograms of (f) and (g) to (i) show other shapes. Hereinafter, a process in which the arithmetic unit 24 calculates the statistical time difference will be described with reference to a histogram.

The arithmetic unit 24 checks that the frequency of the measured time difference corresponding to 0 ° and 360 ° is other than 0, and based on this, determines whether or not the peak of the histogram shape of the compressed frequency data is broken. A determination is made (step S25). "N
In the case of O ", as shown in FIG. 9 (a), (d) or (g), the compression frequency data corresponding to the left side of the mountain is searched for, and the point A1 corresponding to the threshold frequency L1 is searched. (Step S26) On the histogram, the point A1 is translated leftward, and the point of intersection with the leftmost vertical axis indicating a phase difference value of 0 degrees is point A. Similarly, the peak of the mountain A search is made for the compression frequency data corresponding to the right side (step S27), and a point B corresponding to the threshold frequency L1 is selected, which is translated rightward from point B on the histogram to indicate a phase difference value of 360 degrees. The point of intersection with the rightmost vertical axis is point B1.

The distances of the straight line A-A1 from point A to point A1 and the straight line B-B1 from point B to point B1 are measured. The straight line A1-B from the point A1 to the point B is regarded as the same point as the point A and the point B1, and is treated as one continuous straight line. The distance of the straight line A1-B is
It is obtained as the total distance of the measurement distance of A1 and the measurement distance of the straight line B-B1. On the straight line A1-B, a point translated from the point B in the right direction or in the left direction from the point A1 by a distance obtained by dividing the total distance into two is set as the middle point O, and the phase of the compression frequency data corresponding to the middle point O The selected value of the angle difference is set to D0 (step S28). When the midpoint time difference D0 is equal to or greater than 180 degrees (half cycle time), 180 degrees are subtracted from the midpoint time difference D0, as shown in FIGS. The selection time difference is set to D1. If the midpoint time difference D0 is 180 degrees or less, 180 degrees are added to the midpoint time difference D0 to make the selected time difference D1 (step S29).

If the determination in step S25 is "YES", the flow chart shown in FIGS. 9 (b), (c), (e), (f), (h),
Alternatively, as shown in (i), the peak portion in the histogram shape of the compression frequency data has a valley at the center of the left and right peaks. With respect to the left mountain portion, the compression frequency data corresponding to the right side (lower right portion) of the mountain edge is searched, and a point A corresponding to a predetermined frequency L1 is selected (step S30).
Similarly, for the right mountain portion, the compression frequency data corresponding to the left side (lower left portion) of the mountain edge is searched, and a point B corresponding to a predetermined frequency L1 is selected (step S31).

The position at which the straight line AB from the point A to the point B is bisected is set as the middle point O, and the time difference of the compression frequency data corresponding to the middle point O is set as the middle point time difference D0 (step S32).
As shown in (c), (f), or (i), when the midpoint time difference D0 is 180 degrees or more, 180 degrees are subtracted from the midpoint time difference D0 to obtain a selected time difference D1. FIG.
As shown in (e) or (h), when the midpoint time difference D0 is 180 degrees or less, 180 degrees are added from the midpoint time difference D0 to make a selected time difference D1 (step S33).

The calculating section 24 calculates a phase difference value 105, which is a phase angle difference, based on the selected time difference D1, and displays the calculated value on the display section 25.
To enter. The display unit 25 displays the angle of the phase difference value 105 (step S34). Returning to step S11 again,
The measurer operates the panel operation unit 26 according to the phase difference value 105 of the display unit 25, and performs an optimal phase adjustment so that the phase difference becomes 180 degrees.

As shown in FIGS. 3A to 3C, when the histogram of the compression frequency data has a normal distribution, the most frequent time difference is adopted as the selection time difference D1, and the selection time difference D1 is used.
Is adjusted to 180 degrees, the phase adjustment becomes optimal. However, as shown in FIGS. 7D to 7I, when the histogram shape of the compression frequency data is other than the normal distribution, if the statistical time difference is adopted as the selection time difference D1, the peak of the histogram shape may be broken. Adjustment becomes inappropriate. According to the phase adjustment of the present embodiment, in any case of the histogram shape of the compression frequency data, the peak adjustment is optimal without breaking the peak of the histogram shape.

According to the above embodiment, the phase angle difference is calculated using the statistical time difference so that the peak of the histogram shape is not broken in any case of the histogram shape of the compression frequency data. Optimal phase adjustment can be performed based on the indicated value.

Although the present invention has been described based on the preferred embodiment, the time measuring device of the present invention is not limited to the configuration of the above-described embodiment, but rather the configuration of the above-described embodiment. A time measuring device with various modifications and changes made from the above is also included in the scope of the present invention.

[0034]

As described above, in the time measuring device of the present invention, the standardized phase angle difference is displayed as the measurement result, so that each measurement result can be quantitatively determined regardless of the frequency of the input clock signal. Can be compared.

In any case of the histogram shape of the compression frequency data, the phase angle difference is calculated using the statistical time difference so that the peak of the histogram shape is not broken.
Optimal phase adjustment can be performed based on the indicated value of the analog meter.

[Brief description of the drawings]

FIG. 1 is a block diagram of a time measuring device 2 and a signal source 1 to be measured thereof according to a first embodiment of the present invention.

FIG. 2 shows a specific example of the signal source 1 of FIG.

FIG. 3 is a flowchart showing an operation of the time measuring device 2 of FIG.

FIG. 4 is a timing chart for explaining a time difference measurement performed by a time difference measurement unit 22;

FIG. 5 is a timing chart for explaining a cycle measurement performed by the cycle measuring unit 23.

FIG. 6 is a histogram showing a state when calculating a phase difference performed by a calculation unit 24.

FIG. 7 shows an example of a display unit 25 of FIG.

FIG. 8 is a flowchart illustrating an operation of phase adjustment performed by the time measuring device according to the second embodiment of the present invention.

FIGS. 9A to 9I are histograms showing specific examples of compression frequency data.

FIG. 10 is a block diagram of a conventional time measuring device.

[Explanation of symbols]

 Reference Signs List 1 signal source 2 time measuring device 11 optical disk 12 equalizer 13 comparator 14 PLL circuit 21 variable delay unit 22 time difference measuring unit 23 cycle measuring unit 24 arithmetic unit 25 display unit 26 panel operation unit 27 frequency data storage memory 28 cycle data storage memory 101 Data signal 102 Clock signal 103 Frequency data 104 Period data 105 Phase difference value

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Claims (4)

[Claims] 1. A time difference measuring unit that samples time difference between rising or falling of two signals a plurality of times to generate time difference data, a period measuring unit that measures a period of one signal, and based on the time difference data. A calculating unit for calculating a time difference between the two signals by a statistical calculation, calculating a ratio between the calculated statistical time difference and the cycle measured by the cycle measuring unit, and calculating a phase angle difference between the two signals. Characteristic time measuring device. 2. The time measuring device according to claim 1, further comprising a variable delay unit that delays one of the two signals and inputs the delayed signal to the time difference measuring unit. 3. The arithmetic unit displays the time difference data as a histogram, and calculates a period of the period measured by the period measuring unit from an intermediate point of the time difference measured value corresponding to a histogram curve whose frequency is lower than a predetermined threshold. The time measuring device according to claim 2, wherein a time difference measurement value located at a position separated by １ ／ is selected as the statistical time difference. 4. The time measuring device according to claim 1, wherein the arithmetic unit selects and outputs the most frequent time difference measurement value from the time difference data.