JPH10185975A - Electromagnetic interference measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure the timing of electromagnetic wave noise generation of each measuring point by synchronizing a digital device with magnetic field measuring operation of a loop antenna and making the digital device execute the same sequence process and measuring. SOLUTION: A loop antenna-moving device 5 moves a loop antenna 4 to a measuring point in turn, at every time, a timing controller 2 gives timing signal to a digital device 1 and processes predetermined sequence. An antenna 8 for measuring EMI detects electromagnetic wave radiated by the digital device 1, a comparator 9 compares the detected value with the EMI regulation value and generates a trigger signal when exceeding the regulation value. With the trigger signal, a data memory device 7 records timing information during exceeding the regulation value. A central controller 3 instructs the timing controller 2 based on the timing information and cause the digital device 1 execute only sequence process when exceeding the regulation value and meanwhile a magnetic field is measured with the loop antenna 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic interference measuring device, and more particularly to an electromagnetic interference measuring device capable of measuring electromagnetic noise generated from a digital device.

[0002]

2. Description of the Related Art As shown in Japanese Unexamined Patent Application Publication No. 6-58970, a method of arranging several loop antennas in a grid pattern and measuring the near magnetic field, or controlling the position of the loop antenna by a linear stage. There has been proposed a method of measuring a near magnetic field by using the method. Although these measurement methods are effective for roughly examining the intensity distribution of the near magnetic field, it is unclear at what timing of the digital waveform an interfering electromagnetic wave is generated because the digital circuit has an aperiodic waveform. 2. Description of the Related Art Conventionally, an electromagnetic interference measurement device (hereinafter, referred to as a noise source) for examining noise sources on a circuit board on which electronic components are mounted
It is called an EMI measuring device. ) Is disclosed in JP-A-6-5897.
As disclosed in Japanese Patent Publication No. 0, a loop antenna is mounted on a measuring table having a plurality of loop antennas arranged in a grid pattern and a magnetic circuit is measured by mounting a circuit board, which is an object to be measured, on a measuring table. Is known in which the position control is performed to measure the near magnetic field.

[0003]

However, in the above-mentioned conventional EMI measuring apparatus, by examining the intensity distribution of the magnetic field near the circuit board, it is possible to roughly know which part of the circuit board is a noise source. Even if it is possible, it is impossible to measure at what timing electromagnetic wave noise is generated at each measurement point of the digital device because the signal waveform of the digital device is an aperiodic waveform.
An object of the present invention is to solve the above-mentioned drawbacks of the prior art, to synchronize the operation of the digital device and the magnetic field measurement operation by the loop antenna at all the measurement points of the digital device, and execute the same sequence processing on the digital device. It is an object of the present invention to provide an EMI measuring device capable of measuring at what timing electromagnetic wave noise occurs at each measurement point by performing measurement.

[0004]

According to a first aspect of the present invention, a magnetic field near a circuit is measured by moving a loop antenna to each measurement point of a digital device to be measured. A moving means for sequentially moving the loop antenna to a measuring point in the EMI measuring device; and a timing for giving a timing signal to the digital device to perform a predetermined sequence process every time the loop antenna moves to the measuring point. Control means, an EMI measurement antenna for detecting an electromagnetic wave radiated from the digital device at a predetermined position, and a value measured by the EMI measurement antenna and an EMI regulation value are compared.
Comparing means for generating a trigger signal when the control value is exceeded, and storage means for recording timing information when the measured value exceeds the EMI control value based on a trigger signal from the comparison means; On the basis of the timing information recorded in the storage means, an instruction is given to the timing control means to cause the digital device to execute only the sequence processing performed when the measured value exceeds the EMI regulation value, and A central controller for generating a signal and measuring a magnetic field with the loop antenna while the digital device is performing a sequence process. Claim 2
In the EMI measuring apparatus according to the first aspect of the present invention, the central controller moves a loop antenna to each measurement point of the digital device in advance to measure a magnetic field, and exceeds an EMI regulation value at a predetermined frequency. Information on the timing at which an electromagnetic wave is generated is acquired, and based on the timing information, the digital device performs EM at the predetermined frequency.
The digital device has a function of giving an instruction to the timing control means to cause the digital device to execute only the sequence processing performed when an electromagnetic wave exceeding the I regulation value is generated. According to a third aspect of the present invention, in the EMI measuring apparatus according to the first aspect, the EMI measuring antenna is configured to be movable around the digital device over the entire circumference. According to a fourth aspect of the present invention, in the EMI measuring apparatus according to the first aspect, the central controller moves a loop antenna to each measurement point of the digital device in advance to measure a magnetic field, and sets an EMI regulation value. The timing information at which the exceeding electromagnetic wave is generated is acquired, and based on the timing information, the digital device executes only the instruction in which the frequency of generating the electromagnetic wave exceeding the EMI regulation value is higher than a predetermined value. Therefore, a function of giving an instruction to the timing control means is provided. According to a fifth aspect of the present invention, in the EMI measuring apparatus according to the first aspect, the central control device identifies an instruction to be executed by the digital device, and a measurement result when the predetermined instruction is executed is a magnetic field generation information. It has a function to prevent it from being imported. According to a sixth aspect of the present invention, in the EMI measuring apparatus according to the first aspect, a Fourier transform device for transforming a magnetic field measured by the loop antenna into a frequency component, and a frequency component for each frequency component transformed by the Fourier transform device. An antenna calibration coefficient correction for calibrating the amplitude and phase, and a Fourier inverse transform device for obtaining a magnetic field waveform in the vicinity of the digital device from the frequency component of the measurement magnetic field calibrated by the antenna calibration coefficient correction. is there. According to a seventh aspect of the present invention, in the EMI measuring apparatus according to the first aspect, storage means for storing magnetic field measurement results at a plurality of measurement points of the digital device, and a plurality of magnetic fields stored in the storage means The apparatus comprises: an inverse analyzer for obtaining a current distribution of the digital device based on the measurement result; and a forward analyzer for obtaining a radiation magnetic field of the digital device from current distribution information obtained by the inverse analyzer. According to an eighth aspect of the present invention, in the EMI measuring apparatus according to the first aspect, the timing information recorded in the storage means is transmitted to the EMI in a state where a plurality of the digital devices are overlapped.
When an electromagnetic wave is measured by the measurement antenna, the measured value is E.
This is the timing information when the value exceeds the MI regulation value. The invention according to claim 9 is the same as the invention according to claim 1.
In the MI measuring device, the timing information recorded in the storage means is used when the measured value exceeds the EMI regulation value when the electromagnetic wave is measured by the EMI measuring antenna while the digital device is covered with a housing. Of the timing information.

[0005]

Embodiments of the present invention will be described below with reference to the drawings. <Embodiment Corresponding to Claim 1> FIG. 1 is a block diagram showing an example of an embodiment of an EMI measuring apparatus according to the present invention. In FIG. 1, reference numeral 1 denotes a digital device to be measured, 2 denotes a timing control device, 3 denotes a central control device, 4 denotes a loop antenna, 5 denotes a loop antenna moving device, 6 denotes an antenna calibration coefficient correction device, and 7 denotes a data storage device. , 8 are antennas for EMI measurement, and 9 is a comparison device. The central control device 3 includes a CPU and a ROM that stores a microprogram executed by the CPU. The central control device 3 includes a timing control device 2, a loop antenna moving device 5, an antenna calibration coefficient correction device 6, a data storage device 7,
In addition, the EMI measurement of the digital device is performed by the near-field probe 4 while controlling the comparison device 9 as a whole. The EMI measurement antenna 8 detects electromagnetic wave noise radiated from the digital device 1 at a position separated from the digital device 1 by a distance defined by the EMI standard. Comparison device 9
Sends a trigger signal to the central controller 3 only when the electromagnetic noise detected by the EMI measurement antenna 8 exceeds the EMI regulation value. Prior to the magnetic field measurement by the loop antenna 4, the central control device 3 generates a predetermined timing signal by the timing control device 2 and causes the digital device 1 to execute a predetermined sequence process.
The trigger signal from the comparison device 9 is monitored, and timing information when the trigger signal is sent is recorded in the data storage device 7.

[0006] When the magnetic field is measured by the loop antenna 4, the central control device 3 causes the loop antenna moving device 5 to sequentially move the loop antenna 4 to a predetermined measurement position. Then, each time the loop antenna 4 moves to the measurement point, the timing controller 2 is notified that the movement of the near magnetic field probe 4 is completed. Then, the timing control device 2 generates a predetermined timing signal. At this time,
Based on the timing information stored in the data storage device 7, the central control device 3 performs only the sequence processing performed when the electromagnetic wave noise detected by the EMI measurement antenna 8 exceeds the EMI regulation value in the digital device. 1 to cause the timing control device 2 to execute a timing signal. This timing signal is sent to the digital device 1 and the central control device 3.
The digital device 1 executes a predetermined sequence process according to the timing signal. Then, the central control device 3 converts the back electromotive voltage generated in the loop antenna 4 into magnetic field generation information of a frequency specified in advance by the antenna calibration coefficient correction device 6, and stores the magnetic field generation information in the data storage device 7. Let it. As described above, the electromagnetic wave noise radiated from the digital device 1 is measured by the EMI measuring antenna 8, and the sequence processing in which the digital device 1 generates the electromagnetic wave noise exceeding the EMI regulation value is specified in advance, and the specification is performed. By measuring the magnetic field generated by causing the digital apparatus 1 to execute only the performed sequence processing, it is possible to know at what timing an electromagnetic interference wave is generated at each magnetic field measurement point.

<Embodiment Corresponding to Claim 2> FIG.
FIG. 2 is a block diagram showing an example of an embodiment of an EMI measuring device according to the second aspect of the present invention. In FIG. 2, reference numeral 1 denotes a digital device to be measured, 2 a timing controller, 3 a central controller, 4 a loop antenna, 5 a loop antenna moving device, 6 an antenna calibration coefficient correction device, and 7 a data storage device. , 8 are antennas for EMI measurement,
9 is a comparison device. Although the EMI measuring device of this embodiment has the same configuration as the EMI measuring device of FIG. 1 corresponding to claim 1, the central control device 3 has, in addition to the above functions,
The magnetic field is measured by moving the loop antenna 5 to each measurement point of the digital device 1 in advance, and timing information for generating an electromagnetic wave exceeding the electromagnetic interference regulation value at a predetermined frequency is obtained. It has a function of giving an instruction to the control device 2. In addition, the data storage device 7 includes a storage area for storing the measurement result at each measurement point of the digital device 1 together with timing information (information indicating the measurement time point) as a sample value of electromagnetic interference. Prior to the main measurement, the central control device 3 uses the loop antenna moving device 5 to control the loop antenna 4
Is moved to some measurement points of the digital device 1 which is confirmed in advance to operate normally, and the magnetic field is measured.
Each measurement result is stored in the data storage device 7, and at the time of the main measurement, the sample value stored in the data storage device 7 is compared with the EMI regulation value, and the sample value exceeds the EMI regulation value. The timing controller 2 controls the generation of timing signals so that the digital device 1 executes only the sequence processing that has been performed sometimes. And
The central controller 3 converts the back electromotive voltage generated by the loop antenna 4 into magnetic field generation information of a frequency specified in advance by the antenna calibration coefficient correction 6, and stores the magnetic field generation information in the data storage device 7. As described above, the digital device 1 specifies a sequence process that generates electromagnetic wave noise exceeding the EMI regulation value, and causes the digital device 1 to execute only the specified sequence process to measure the magnetic field generated. The measurement can be performed efficiently and the measurement time can be reduced.

<Embodiment Corresponding to Claim 3> FIG.
FIG. 3 is a block diagram showing an example of an embodiment of an EMI measuring device according to the third aspect of the present invention. The device configuration shown in FIG. 3 further includes an antenna moving device 10 for moving the EMI measurement antenna 8 with respect to the digital device 1 to be measured in addition to the device configuration of FIG. That is, the EMI measurement antenna 8 is connected to the digital device 1.
Is configured to be movable around the entire circumference, and is moved to an arbitrary position by the antenna moving device 10. Prior to the measurement of the magnetic field by the loop antenna 4, the central control device 3 causes the timing control device 2 to generate a predetermined timing signal, and causes the digital device 1 to execute a predetermined sequence process. And
While controlling the antenna moving device 10 to move the EMI measurement antenna 8 so that the movement locus thereof surrounds the digital device 1 in a cylindrical shape, the trigger signal from the comparison device 9 is monitored, and the trigger signal is sent. The timing information at the time of the occurrence is recorded in the data storage device 7. As a result, it is possible to measure electromagnetic noise radiated in all directions around the digital device 1 and obtain timing information at which the electromagnetic noise exceeds the EMI regulation value.

When the near magnetic field is measured by the loop antenna 4, the electromagnetic noise detected by the EMI measurement antenna 8 exceeds the EMI regulation value based on the timing information stored in the data storage device 7. The timing controller 2 controls the generation of timing signals so that the digital device 1 executes only the sequence processing that has been performed sometimes. Then, the central controller 3 converts the back electromotive voltage generated by the loop antenna 4 into magnetic field generation information of a frequency specified in advance by the antenna calibration coefficient correction 6, and stores the magnetic field generation information in the data storage device 7. . As described above, the electromagnetic wave noise radiated in all directions from the digital device 1 is measured by the EMI measurement antenna 8, and the digital device 1 specifies the sequence processing for generating the electromagnetic wave noise exceeding the EMI regulation value. By measuring the near magnetic field generated by causing the digital device 1 to execute only the specified sequence processing, the near magnetic field exceeding the EMI regulation value at an arbitrary measurement point can be more accurately and efficiently measured.

<Embodiment Corresponding to Claim 4> FIG.
FIG. 4 is a block diagram showing an example of an embodiment of an EMI measuring apparatus according to the invention of claim 4. In FIG. 4, reference numeral 1 denotes a digital device to be measured, 2 denotes a timing control device, 3 denotes a central control device, 4 denotes a loop antenna, 5 denotes a loop antenna moving device, 6 denotes an antenna calibration coefficient correction device, and 7 denotes a data storage device. , 8 are antennas for EMI measurement,
9 is a comparison device. Although the EMI measuring device of this embodiment has the same configuration as the EMI measuring device of FIG. 1 corresponding to claim 1, the central control device 3 has, in addition to the above functions,
The magnetic field is measured by moving the loop antenna 4 to each measurement point of the digital device 1 in advance, and the timing information at which the electromagnetic wave exceeding the electromagnetic interference limit value is generated is acquired, and based on the timing information, the digital device 1 It has a function of giving an instruction to the timing control device 2 so as to cause the digital device 1 to execute only an instruction in which the frequency of generating an electromagnetic wave exceeding the electromagnetic interference regulation value is higher than a predetermined value. In addition, the data storage device 7 includes a storage area for storing the measurement result at each measurement point of the digital device 1 together with timing information (information indicating the measurement time point) as a sample value of electromagnetic interference.

Prior to the main measurement, the central control unit 3 controls the digital device 1 which has been confirmed in advance by the loop antenna moving device 5 to operate the loop antenna 4 normally.
Are moved to some measurement points, and the magnetic field is measured. Each measurement result is stored in the data storage device 7. In this measurement, the sample value stored in the data storage device 7 and E
The timing control unit 2 controls the generation of a timing signal by the timing control unit 2 so that the digital device 1 executes only an instruction in which the frequency of generating an electromagnetic wave exceeding the electromagnetic wave disturbance control value is higher than a predetermined value by comparing with the MI control value. Then, the central controller 3 converts the back electromotive voltage generated by the loop antenna 4 into magnetic field generation information of a frequency specified in advance by the antenna calibration coefficient correction 6, and stores the magnetic field generation information in the data storage device 7. . As described above, the digital device 1 specifies an instruction that is likely to generate electromagnetic wave noise exceeding the EMI regulation value, and only the specified instruction is used by the digital device 1.
EM by measuring the magnetic field generated by
The measurement time can be shortened by performing the I measurement more accurately and efficiently.

<Embodiment Corresponding to Claim 5> FIG.
FIG. 7 is a block diagram showing an example of an embodiment of an EMI measuring device according to the invention of claim 5. The device configuration shown in FIG. 5 includes, in addition to the device configuration shown in FIG. 1, an instruction executed by the digital device 1 is identified, and when a predetermined instruction unrelated to a normal operation is executed, for example, when an interrupt process is performed. Has the function of not taking in the measurement results in the magnetic field generation information. The central control device 3 controls the timing control device 2, the loop antenna moving device 5, the antenna calibration coefficient correction device 6, the data storage device 7, and the comparison device 9 while controlling the EMI of the digital device by the near-field probe 4. Do. At this time, the central control device 3 causes the loop antenna moving device 5 to sequentially move the loop antenna 4 to a predetermined measurement position. Then, each time the loop antenna 4 moves to the measurement point, the timing controller 2 is notified that the movement of the loop antenna 4 has been completed. Then, the timing control device 2 generates a predetermined timing signal. This timing signal is sent to the digital device 1 and the central control device 3. The digital device 1 executes a predetermined sequence process according to the timing signal. On the other hand, the central control device 3 converts the back electromotive voltage generated in the loop antenna 4 into magnetic field generation information of a frequency specified in advance by the antenna calibration coefficient correction device 6 while monitoring the instructions executed by the digital device 1. When a predetermined instruction such as an interrupt process is executed, only the near magnetic field information other than the instruction being executed is stored in the data storage device 7. As described above, it is possible to eliminate the influence of the predetermined instruction unrelated to the normal operation and always accurately measure only the electromagnetic wave noise during the execution of the normal sequence processing.

<Embodiment Corresponding to Claim 6> FIG.
FIG. 7 is a block diagram showing an example of an embodiment of an EMI measuring device according to the invention of claim 6. The device configuration shown in FIG. 6 is a Fourier transform device 1 for converting the magnetic field measured by the loop antenna 4 into frequency components in addition to the device configuration of FIG.
1, an antenna calibration coefficient correction device 12 that performs amplitude and phase calibration for each frequency component converted by the Fourier transform device 11, and an antenna calibration coefficient correction device 12
And a Fourier inverse transform device 13 that converts the frequency component of the measurement magnetic field calibrated by the above into a near magnetic field waveform near the digital device 1, that is, a current waveform. The central control device 3 includes a timing control device 2, a probe moving device 5, a loop antenna moving device 5, an antenna calibration coefficient correcting device 6, a data storage device 7, a comparing device 9, a Fourier transform device 11, an antenna calibration coefficient correcting device 12,
The EMI measurement of the digital device is performed by the loop antenna 4 while controlling the Fourier inverse transform device 13 as a whole.
At this time, the central control device 3 causes the probe moving device 5 to sequentially move the loop antenna 4 to a predetermined measurement position.
Then, each time the loop antenna 4 moves to the measurement point, the timing controller 2 is notified that the movement of the loop antenna 4 has been completed. Then, the timing control device 2 generates a predetermined timing signal. This timing signal is sent to the digital device 1 and the central control device 3.
The digital device 1 executes a predetermined sequence process according to the timing signal. On the other hand, the central control device 3 converts the back electromotive voltage generated by the loop antenna 4 in response to the electromagnetic noise from the digital device 1 into magnetic field generation information of a frequency specified in advance by the antenna calibration coefficient correction device 6, The magnetic field generation information is stored in the data storage device 7.

When a series of magnetic field measurement processes is completed and the central control device 3 wants to measure a nearby current waveform at a certain measurement position at a certain time, the loop antenna moving device 5 moves the loop antenna 4 to a predetermined position. Moving. And
A timing signal generation instruction is given to the timing control device 2 to cause the digital device 1 to perform predetermined sequence processing. When a predetermined time comes, the Fourier transform device 1
1, the near magnetic field measured at a predetermined time by the loop antenna 4 is converted into a frequency component, and the antenna calibration coefficient correction device 12 performs amplitude and phase calibration for each frequency component, and then performs an inverse Fourier transform. The device 13 converts the frequency component of the measured magnetic field into a nearby magnetic field waveform, that is, a current waveform, and stores the current waveform information in the data storage device 7. As described above, the current waveform at an arbitrary measurement point at an arbitrary time can be measured, and more effective EMI countermeasures can be performed based on the information.

<Embodiment Corresponding to Claim 7> FIG.
FIG. 7 is a block diagram showing an example of an embodiment of an EMI measuring device according to the invention of claim 7. The device configuration shown in FIG. 7 includes, in addition to the device configuration of FIG. 1, an inverse analysis device 14 that obtains a current distribution of the digital device 1 based on a plurality of near-field measurement results stored in the data storage unit 7. And a forward analyzer 15 for obtaining a radiated near magnetic field of the digital device 1 from the current distribution information obtained by the analyzer 14. The central control device 3 includes a timing control device 2, a loop antenna moving device 5, an antenna calibration coefficient correction device 6, a data storage device 7, a comparison device 9, and an inverse analysis device 1.
The EMI measurement of the digital device is performed by the near-field probe 4 while controlling the forward analysis device 4 and the forward analysis device 15. At this time, the central control device 3 causes the loop antenna moving device 5 to sequentially move the loop antenna 4 to a predetermined measurement position. Then, each time the loop antenna 4 moves to the measurement point, the timing controller 2 is notified that the movement of the loop antenna 4 has been completed. Then, the timing control device 2 generates a predetermined timing signal. This timing signal is sent to the digital device 1 and the central control device 3. The digital device 1 executes a predetermined sequence process according to the timing signal. On the other hand, the central control device 3 converts the back electromotive force generated by the near magnetic field probe 4 in response to the electromagnetic noise from the digital device 1 into the near magnetic field information in the time domain of the frequency previously specified by the antenna calibration coefficient correction device 6. And the near magnetic field information is stored in the data storage device 7. And the central control device 3
When the measurement of the near magnetic field at all the measurement points and the recording to the data storage device 7 are completed, a plurality of near magnetic field information stored in the data storage device 7 are read and sent to the inverse analysis device 14. Then, the inverse analysis device 14 obtains a current distribution of the digital device 1 based on a plurality of pieces of near magnetic field information. Further, the central control device 3 sends the current distribution information obtained by the inverse analysis device 14 to the forward analysis device 15 to calculate the radiated near magnetic field of the digital device 1 from the current distribution information. The calculation formula of the radiation near magnetic field H used in the forward analysis device 15 is expressed by the following formula (1).

[0016]

(Equation 1) Here, J is the current distribution in the volume v, r is the distance from the source to the measurement point, and β is the wave number. By the above processing, it is possible to predict in advance how much the radiated near magnetic field can be reduced when the current value at an arbitrary position of the digital device 1 is reduced, and based on the information, a more effective EMI measure can be taken. It can be carried out.

<Embodiment Corresponding to Claim 8> FIG.
FIG. 9 is a block diagram showing an example of an embodiment of an EMI measuring device according to the invention of claim 8. In FIG. 8, reference numeral 1 denotes a digital device to be measured, 2 denotes a timing control device, 3 denotes a central control device, 4 denotes a loop antenna, 5 denotes a loop antenna moving device, 6 denotes an antenna calibration coefficient correction, and 7
Is a data storage device, 8 is an antenna for EMI measurement, and 9 is a comparison device. In this embodiment, the loop antenna 4
Prior to the measurement of the magnetic field, the timing control device 2 generates a predetermined timing signal in a state where a plurality of digital devices 1 are superimposed, and causes the digital device 1 to execute a predetermined sequence process, and The trigger signal is monitored, and timing information when the trigger signal is sent is recorded in the data storage device 7. When the magnetic field is measured by the loop antenna 4, the digital devices 1 are placed one by one, and the measurement is performed in exactly the same manner as in the first embodiment. That is,
In a state where a plurality of digital devices 1 are stacked, timing information when an electromagnetic wave exceeding the EMI regulation value is generated is acquired in advance, and based on the timing information,
The magnetic field is measured by the loop antenna 4 while causing the digital device 1 to execute only the sequence processing that has been performed when an electromagnetic wave exceeding the EMI regulation value is generated. As described above, when a plurality of digital devices 1 are stacked,
A plurality of digital devices 1 were overlapped by specifying a sequence process that generates an electromagnetic wave noise exceeding the MI regulation value and causing each of the digital devices 1 to execute only the specified sequence process and measuring the near magnetic field generated. The magnetic field of each digital device 1 that is correlated with the occurrence of electromagnetic wave noise in the state can be measured, and more effective EMI countermeasures can be taken based on the information.

<Embodiment Corresponding to Claim 9> FIG.
FIG. 9 is a block diagram showing an example of an embodiment of an EMI measuring device according to the ninth aspect of the present invention. In FIG. 9, reference numeral 1 denotes a digital device as an object to be measured, 2 denotes a timing control device, 3 denotes a central control device, 4 denotes a loop antenna, 5 denotes a loop antenna moving device, 6 denotes an antenna calibration coefficient correction,
Is a data storage device, 8 is an antenna for EMI measurement, and 9 is a comparison device. In this embodiment, the loop antenna 4
Prior to the magnetic field measurement by the
In the state where the trigger signal is received by the timing control device 2, a predetermined timing signal is generated by the timing control device 2 to cause the digital device 1 to execute a predetermined sequence process, while monitoring the trigger signal from the comparison device 9, and The timing information at the time of transmission is recorded in the data storage device 7. When the magnetic field is measured by the loop antenna 4, the housing 16 is removed, and the measurement is performed in exactly the same manner as in the first embodiment. That is, in a state where the digital device 1 is housed in the housing 16, timing information when an electromagnetic wave exceeding the EMI regulation value is generated is acquired in advance, and based on the timing information,
The magnetic field measurement by the loop antenna 4 is performed while causing each digital device 1 to execute only the sequence processing that has been performed when an electromagnetic wave exceeding the EMI regulation value is generated. In this way, when a plurality of digital devices 1 are superimposed, a sequence process that generates electromagnetic wave noise exceeding the EMI regulation value is specified, and only the specified sequence process is executed by the digital device 1 to measure a near magnetic field generated. By doing so, it is possible to measure the magnetic field of each digital device 1 that is correlated with the generation of electromagnetic noise when the digital device 1 is housed in the housing 16, and based on that information, a more effective EMI measures can be taken.

[0019]

As described above, according to the present invention, the following excellent effects can be exhibited. According to the first aspect of the present invention, there is provided an EMI measuring apparatus for measuring a near magnetic field near a circuit by moving a near magnetic field probe to each measurement point of a digital device to be measured. Is actually measured by the EMI measurement antenna, the digital device specifies a sequence process that generates electromagnetic wave noise exceeding the EMI regulation value, and every time the near magnetic field probe is moved to the measurement point, only the specified sequence process is performed. Because it was configured to measure the magnetic field with the loop antenna while executing it on the digital device,
At all measurement points of the digital device, the same sequence processing can be executed by the digital device to efficiently perform the measurement, and as a result, to know at what timing the electromagnetic noise occurs at each measurement point Can be. According to the second aspect of the present invention, in addition to the effect of the first aspect, the magnetic field is measured by moving the loop antenna to each measurement point of the digital device in advance, and exceeds the EMI regulation value at a predetermined frequency. Since the timing information at which the electromagnetic wave is generated is acquired, and based on the timing information, only the sequence processing that has been performed when the electromagnetic noise exceeding the EMI regulation value is generated is performed by the digital device, and the measurement is performed while performing the measurement. The measurement can be performed more accurately and efficiently.

According to the third aspect of the present invention, in addition to the effect of the first aspect, by measuring the electromagnetic wave noise from the digital device while moving the EMI measurement antenna, all directions from the digital device can be measured. Since the radiated electromagnetic noise can be measured, the digital device can more accurately specify the sequence processing that generates the electromagnetic wave noise exceeding the EMI regulation value, and the digital device executes only the specified sequence processing to generate the generated electromagnetic noise. By measuring the near magnetic field, the near magnetic field exceeding the EMI regulation value at an arbitrary measurement point can be measured more accurately and efficiently. According to the fourth aspect of the present invention, in addition to the effect of the first aspect, the digital device specifies an instruction that easily generates electromagnetic wave noise exceeding the EMI regulation value, and only the specified instruction is transmitted to the digital device. By measuring the magnetic field generated by the execution, the EMI measurement can be performed more accurately and efficiently, and the measurement time can be reduced.

According to the fifth aspect of the invention, in addition to the effect of the first aspect, the measurement result at the time of executing a predetermined instruction unrelated to a normal operation can be prevented from being taken in as magnetic field generation information. Therefore, it is possible to eliminate the influence of the predetermined instruction unrelated to the normal operation and always accurately measure only the electromagnetic wave noise during the execution of the normal sequence processing. According to the sixth aspect of the invention, in addition to the effect of the first aspect, a current waveform at an arbitrary measurement point at an arbitrary time can be measured, and a more effective EMI can be measured based on the information. Measures can be taken.

According to a seventh aspect of the present invention, in addition to the effect of the first aspect, the current distribution of the digital device is obtained based on the magnetic field measurement results at a plurality of measurement points, and the radiation of the digital device is obtained from the current distribution information. Since the near magnetic field can be obtained, it is possible to predict in advance how much the radiated magnetic field can be reduced when the current value at an arbitrary position of the digital device is reduced, and to effectively perform EMI countermeasures. According to the eighth aspect of the present invention, in addition to the effect of the first aspect, the EMI in a state where a plurality of digital devices are superimposed is provided.
By specifying the sequence processing that generates electromagnetic noise exceeding the regulated value, and by executing the specified sequence processing only on each digital device and measuring the near magnetic field generated, the digital device in a state where a plurality of digital devices are overlapped The magnetic field of each digital device correlated with the generation of electromagnetic wave noise can be measured, and more effective EMI countermeasures can be taken based on the information.

According to the ninth aspect of the present invention, in addition to the effect of the first aspect, a sequence process for generating electromagnetic wave noise exceeding an EMI regulation value in a state in which a plurality of digital devices are superimposed is specified and specified. Measures the near magnetic field generated by causing the digital device to execute only the performed sequence processing, thereby measuring the magnetic field of each digital device that is correlated with the generation of electromagnetic noise when the digital device is housed in the housing. And more effective EMI countermeasures can be taken based on the information.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an example of an embodiment of an electromagnetic interference measuring apparatus according to the first aspect of the present invention.

FIG. 2 is a block diagram showing an example of an embodiment of an electromagnetic interference measuring device according to the invention described in claim 2;

FIG. 3 is a block diagram showing an example of an embodiment of an electromagnetic interference measuring device according to the invention described in claim 3;

FIG. 4 is a block diagram showing one example of an embodiment of an electromagnetic interference measuring apparatus according to the invention described in claim 4;

FIG. 5 is a block diagram showing an example of an embodiment of an electromagnetic wave interference measuring device according to the invention described in claim 5;

FIG. 6 is a block diagram showing an example of an embodiment of an electromagnetic interference measuring device according to the invention described in claim 6;

FIG. 7 is a block diagram showing an example of an embodiment of an electromagnetic interference measuring apparatus according to the invention described in claim 7;

FIG. 8 is a block diagram showing an example of an embodiment of an electromagnetic interference measuring device according to the invention described in claim 8;

FIG. 9 is a block diagram showing an example of an embodiment of an electromagnetic interference measuring device according to the invention of claim 9;

[Explanation of symbols]

1 digital device, 2 timing control device, 3 central control device (measuring means), 4 loop antenna, 5 loop antenna moving device, 6 antenna calibration coefficient correction device, 7 data storage device, 8 EMI measurement antenna,
Reference Signs List 9 comparison device, 10 antenna moving device, 11 Fourier transform device, 12 antenna calibration coefficient correction device, 13
Fourier inverse transformation device, 14 inverse analysis device, 15 forward analysis device, 16 housings.

Claims (9)

[Claims] 1. An electromagnetic interference measuring apparatus for measuring a magnetic field near a circuit by moving a loop antenna to each measurement point of a digital device as an object to be measured, and a moving means for sequentially moving the loop antenna to a measurement point. Each time the loop antenna moves to a measurement point, a timing control means for giving a timing signal to the digital device to perform a predetermined sequence process; and an electromagnetic wave radiated from the digital device at a predetermined position. An electromagnetic interference measuring antenna to be detected, a comparing means for comparing a measured value of the electromagnetic interference measuring antenna with the electromagnetic interference regulated value, and generating a trigger signal when the measured value exceeds the electromagnetic interference regulated value; Based on the trigger signal from the comparing means, the timing information when the measured value exceeds the electromagnetic interference limit value is recorded. Based on the timing information recorded in the storage means, the timing control to cause the digital device to execute only the sequence processing performed when the measured value exceeds the electromagnetic interference limit value. A central control unit for giving instructions to the means to generate a timing signal and for measuring a magnetic field by the loop antenna while the digital device is performing a sequence process. Obstacle measuring device. 2. The storage unit has a storage area for storing measurement results at a plurality of measurement points of the digital device as sample values of electromagnetic interference, and the central control unit stores the measurement result in the storage unit. Compare the stored sample value with the electromagnetic interference limit value,
A function of instructing the timing control means to generate a timing signal so as to cause the digital device to execute only the sequence processing performed when the sample value exceeds the electromagnetic interference limit value. Item 2. The electromagnetic interference measuring device according to Item 1. 3. The electromagnetic interference measuring apparatus according to claim 1, wherein the electromagnetic interference measuring antenna is configured to be movable around the digital device. 4. The central control device moves a loop antenna to each measurement point of the digital device, measures a magnetic field in advance, and acquires timing information at which an electromagnetic wave exceeding an electromagnetic interference limit value is generated. A function of giving an instruction to the timing control means in order to cause the digital device to execute only instructions in which the frequency of generating the electromagnetic wave exceeding the electromagnetic interference limit value is higher than a predetermined value based on the timing information. 2. The electromagnetic interference measuring device according to claim 1, wherein: 5. The electromagnetic interference apparatus according to claim 1, wherein the central control unit identifies an instruction executed by the digital device, and does not capture a measurement result at the time of executing the predetermined instruction as magnetic field generation information. measuring device. 6. A Fourier transform device for converting a magnetic field measured by the loop antenna into a frequency component, an antenna calibration coefficient correction for calibrating an amplitude and a phase for each frequency component converted by the Fourier transform device, 2. The electromagnetic interference measurement apparatus according to claim 1, further comprising: an inverse Fourier transform apparatus for obtaining a magnetic field waveform near the digital device from a frequency component of the measurement magnetic field calibrated by the antenna calibration coefficient correction. 7. A storage device for storing magnetic field measurement results at a plurality of measurement points of the digital device, and an inverse analysis for obtaining a current distribution of the digital device based on the plurality of magnetic field measurement results stored in the storage device. 2. The electromagnetic wave interference measuring device according to claim 1, further comprising: a means for analyzing the radiated magnetic field of the digital device from the current distribution information obtained by the inverse analyzing means. 8. The timing information recorded in the storage means is such that when an electromagnetic interference wave is measured by the electromagnetic wave interference measurement antenna in a state where a plurality of the digital devices are superimposed, the measured value of the electromagnetic interference wave is an electromagnetic wave. 2. The timing information when a fault regulation value is exceeded.
An electromagnetic interference measuring device according to the above. 9. The timing information recorded in the storage means is such that when an electromagnetic interference is measured by the electromagnetic interference measuring antenna with the digital device covered with a casing, the measured value of the electromagnetic interference is 2. The timing information when a regulation value is exceeded.
An electromagnetic interference measuring device according to the above.