JP2011180099A - Device for magnetic near-field measurement, method for current pattern specification, and program for current pattern specification - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device for magnetic near-field measurement for specifying a noise current which is a generation source of an unnecessary electromagnetic wave radiated from an electronic apparatus. <P>SOLUTION: A means for synthesizing magnetic field distribution chart extracts a part where a maximal value of magnetic field intensity exists, based on an intensity distribution of horizontal components and vertical components of a near magnetic field of an inputted measuring object, and generates a synthesized distribution chart. An array code extraction means scans the synthesized distribution chart in the longitudinal direction and in the lateral direction, and extracts an array code showing a state where a domain on which the maximal value of the intensity of horizontal components and vertical components of the magnetic field exists is arrayed. An operation means compares the intensity of each magnetic field of the plurality of vertical components which are elements of the array code with respect to a specific array code, and adds the comparison results to the array code, to thereby generate an array code for retrieval. A retrieval means retrieves a storage device 21 based on the array code for retrieval, and specifies a current pattern in the synthesized distribution chart. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a near magnetic field measuring device, a current pattern identifying method, and a current pattern identifying program, and particularly suitable for use in identifying a noise current that is a source of unnecessary electromagnetic waves radiated from an electronic device or the like. The present invention relates to a magnetic field measuring apparatus, a current pattern specifying method, and a current pattern specifying program.

  An electromagnetic wave radiated from the electronic device may interfere with other electronic devices, and malfunction may occur in an electronic device different from the radiation source. In recent years, for example, in wireless portable terminals such as mobile phones, there is a concern that electromagnetic waves generated in the terminals may interfere with wireless circuits due to advanced functions and high-density mounting of electronic components, resulting in a deterioration in wireless communication quality. It has been pointed out that there is. As an effort to reduce these unnecessary electromagnetic waves (electromagnetic interference waves), electronic device development companies, etc., use near magnetic field measurement equipment to investigate the electromagnetic field distribution on the housing surface of the electronic device and the component mounting substrate surface, Product developers estimate noise currents related to radiation of electromagnetic interference, change circuit design, and take measures to reduce electromagnetic interference such as metal shields and magnetic sheets.

  However, when investigating a place where unnecessary electromagnetic waves are radiated, a product developer or the like estimates based on a magnetic field strength distribution obtained by measuring a magnetic field near the object to be measured. In this case, the noise emission location is largely determined by the developer's skill, adding unnecessary noise countermeasure components, resulting in an increase in product cost, taking a lot of time for analysis, and delaying the product development schedule. There are problems such as. For this reason, a device for identifying a noise current that is a source of unnecessary electromagnetic waves radiated from an electronic device is required.

As this type of related technology, for example, there is a semiconductor evaluation apparatus described in Patent Document 1.
In this semiconductor evaluation apparatus, the two-dimensional electromagnetic field distribution in a plane parallel to the upper surface of the semiconductor is measured by the electromagnetic field measuring means. The distribution image generating means extracts an electromagnetic field distribution larger than a predetermined threshold from the semiconductor electromagnetic field distribution measured by the electromagnetic field measuring means, and the electromagnetic field distribution is a distribution image in a two-dimensional plane. Is converted to The image collating unit collates the distribution image generated by the distribution image generating unit with the semiconductor wiring and lead frame projection image generated in advance. When the electromagnetic field distribution and the image of the wiring or the lead frame overlap by the collation by the image collating unit, the overlapping wiring or the lead frame is identified as a noise radiation source.

  Further, in the near electromagnetic field measurement system described in Patent Document 2, the distribution of the near electromagnetic field generated from the circuit board is measured, and the measurement position information and the circuit pattern design position information are matched to obtain the circuit pattern design information. The electromagnetic field measurement result is displayed above. Then, the electromagnetic field measurement result is associated with the wiring or plane pattern as the circuit pattern design information.

  Moreover, in the current estimation apparatus described in Patent Document 3, the distribution of magnetic field components in one or more directions on the printed wiring board is measured based on the detected current by the magnetic field distribution measuring unit. A current density model is stored in the database. A radiation field pattern generator generates a radiation field pattern from the current density model stored in the database. The current density model array generator generates an in-plane current density model array on the printed wiring board from the current detected by the magnetic field distribution measuring means and the current density model stored in the database. The current density calculator obtains the current density distribution using the arrangement of the current density model generated by the current density model array generator and the radiated magnetic field pattern generated by the radiated magnetic field pattern generator.

JP 2000-074969 A JP 2004-198232 A Japanese Patent Laid-Open No. 11-014671

However, the related technology has the following problems.
That is, in the semiconductor evaluation apparatus described in Patent Document 1, the radiation noise of the semiconductor is accurately measured, but the configuration and processing method are different from the present invention.

  In the near electromagnetic field measurement system described in Patent Document 2, the noise source at the time of high-density mounting is specified at high speed, but the configuration and processing method are different from the present invention.

  In the current estimation device described in Patent Document 3, the distribution of the current flowing on the printed wiring board is required with high reliability, but the configuration and processing method are different from the present invention.

  The present invention has been made in view of the above circumstances, and a near magnetic field measuring device that identifies a noise current that is a source of unwanted electromagnetic waves radiated from an electronic device or the like, a current pattern identifying method used in the device, and the like The purpose is to provide a current pattern identification program.

  In order to solve the above-described problems, a first configuration of the present invention relates to a near magnetic field measuring apparatus, and relates to a horizontal component and a vertical component of a near magnetic field detected by a magnetic field detecting unit with respect to a predetermined surface of an object to be measured. Based on the intensity distribution, a portion where the maximum value of the magnetic field strength exists is extracted and combined to generate a combined distribution map, and the combined distribution map generated by the magnetic field distribution map combining means An array code extracting means for scanning in the vertical direction and the horizontal direction and extracting an array code representing a state in which the regions where the maximum values of the horizontal component and the vertical component of the magnetic field are present are arranged; Compare the strength of magnetic fields of a plurality of vertical components that are elements of the sequence code with respect to a specific sequence code among the sequence codes extracted by the means, and search by adding the comparison result to the sequence code Sequence code for Based on the calculation means to be generated, storage means in which a current pattern corresponding to the search sequence code generated by the calculation means is stored in advance as a database, and the search sequence code generated by the calculation means And a search means for searching the database and specifying a current pattern in the composite distribution map.

  According to a second configuration of the present invention, there is provided a current pattern specifying method, wherein the magnetic field distribution diagram combining means detects the intensities of the horizontal and vertical components of the near magnetic field detected by the magnetic field detecting means with respect to a predetermined surface of the object to be measured. Based on the distribution, a portion where the maximum value of the magnetic field strength exists is extracted and combined to generate a combined distribution map, and an array code extraction unit is generated by the magnetic field distribution map combining unit. An array code extraction process for extracting an array code representing a state in which regions where the maximum values of the horizontal component and the vertical component of the magnetic field are present are arranged by scanning the composite distribution chart in the vertical direction and the horizontal direction; The arithmetic means compares the magnetic field strengths of a plurality of vertical components that are elements of the array code against the specific array code of the array codes extracted by the array code extraction means, and the comparison result The concerned A calculation process for generating a search sequence code in addition to the column code; a storage process for storing in advance a current pattern corresponding to the search sequence code generated by the calculation unit as a database; and a search unit However, the database is searched based on the search sequence code generated by the calculation means, and a search process for specifying a current pattern in the composite distribution diagram is performed.

  According to the configuration of the present invention, it is possible to realize a near magnetic field measuring apparatus that specifies a current pattern of an object to be measured.

It is a block diagram which shows the structure of the principal part of the near magnetic field measuring apparatus which is one Embodiment of this invention. It is a figure which shows the concept of the horizontal component and vertical component of a near magnetic field input into the magnetic field distribution map synthetic | combination part 11 from the input device 1 in FIG. It is a flowchart explaining operation | movement of the near magnetic field measuring apparatus of FIG. It is a figure explaining the example of near magnetic field intensity distribution in case the electric current is flowing through the wiring of a component mounting board. It is a figure explaining the process performed in the magnetic field distribution map synthetic | combination part. It is a figure explaining the process performed in the arrangement | sequence code extraction part. 3 is a diagram illustrating an example of a database stored in a storage device 21. FIG. 3 is a diagram illustrating an example of a database stored in a storage device 21. FIG.

  The magnetic field distribution map combining means (magnetic field distribution combining unit) extracts from the maximum value of the magnetic field strength to a predetermined level lower than the same maximum value, and the maximum values of the horizontal component and the vertical component of the magnetic field exist. A near magnetic field measuring apparatus configured to generate the composite distribution diagram by separating and combining so that regions do not overlap is realized.

  Further, the magnetic field distribution map synthesis means (magnetic field distribution map synthesis unit) extracts from the maximum value of the magnetic field intensity to a level 3 dB lower than the same maximum value. The array code extracting means (array code extracting unit) scans the composite distribution chart in the vertical direction and the horizontal direction, and detects three or more regions where the maximum values of the horizontal component and the vertical component of the magnetic field exist. In this case, the sequence code is extracted as the sequence code. The arithmetic means (arithmetic unit) is configured such that the arrangement code extracted by the arrangement code extraction means (arrangement code extraction unit) is composed of at least two horizontal components and three vertical components, and In the state where the horizontal components are alternately arranged, when the intensity of the magnetic field of the vertical component at the center is stronger than the vertical component at both ends, the comparison result shows that the current corresponding to the two horizontal components is When the strength of the magnetic field of the vertical component at the center is weaker than the vertical component at both ends while the states are opposite to each other, the comparison result indicates that the currents corresponding to the two horizontal components are in the same direction. It is supposed to be configured. The storage means (storage device) stores the position and direction of the current as the current pattern corresponding to the search array code. The search means (search unit) searches the database and identifies the position and direction of the current in the composite distribution diagram.

Embodiment

FIG. 1 is a block diagram showing a configuration of a main part of a near magnetic field measuring apparatus according to an embodiment of the present invention.
As shown in the figure, the near magnetic field measuring apparatus of this embodiment includes an input device 1, an analysis system 10, a storage device 21, and an output device 22. The input device 1 is, for example, a data reading device such as a floppy (registered trademark) disk drive or a keyboard of a computer, and is provided on a predetermined surface (for example, a housing surface of an electronic device or a component mounting substrate surface) of a device under test. On the other hand, the intensity distribution of the horizontal component and the vertical component of the near magnetic field detected by a magnetic field probe (magnetic field detection means) (not shown) is input.

  The analysis system 10 is configured by a computer that functions based on a current pattern specifying program, and includes a magnetic field distribution diagram synthesis unit 11, an array code extraction unit 12, a calculation unit 13, and a search unit 14. The magnetic field distribution diagram combining unit 11 extracts a portion where the maximum value of the magnetic field strength exists based on the strength distribution of the horizontal component and the vertical component of the near magnetic field input from the input device 1, and synthesizes the combined distribution diagram. Generate. In particular, in this embodiment, the magnetic field distribution map synthesis unit 11 extracts from the maximum value of the magnetic field strength to a level lower than the same maximum value (for example, a level 3 dB lower), and the same strength of the horizontal component and the vertical component of the magnetic field. A region in which the maximum value exists is separated and combined so as not to overlap to generate a combined distribution map. The array code extraction unit 12 scans the combined distribution map generated by the magnetic field distribution map combining unit 11 in the vertical direction and the horizontal direction, and the region where the maximum values of the horizontal component and the vertical component of the magnetic field exist is arranged. The sequence code that represents the current state is extracted. In particular, in this embodiment, the array code extraction unit 12 scans the composite distribution diagram in the vertical direction and the horizontal direction, and detects three or more regions where the maximum values of the horizontal component and the vertical component of the magnetic field exist. If so, it is extracted as the sequence code.

  The calculation unit 13 compares the magnetic field strengths of a plurality of vertical components that are elements of the sequence code with respect to a specific sequence code among the sequence codes extracted by the sequence code extraction unit 12, and determines the comparison result. In addition to the sequence code, a search sequence code is generated. In particular, in this embodiment, the calculation unit 13 includes, for example, the arrangement code extracted by the arrangement code extraction unit 12 including two horizontal components and three vertical components, and the vertical components and the horizontal components are alternately arranged. When the intensity of the magnetic field of the central vertical component is stronger than the vertical component at both ends, the above comparison results show that the currents corresponding to the two horizontal components are in directions opposite to each other, When the intensity of the magnetic field of the central vertical component is weaker than that of the vertical component, the comparison result is such that the currents corresponding to the two horizontal components are in the same direction.

  The storage device 21 is composed of, for example, an external storage medium or a hard disk, and a current pattern corresponding to the search arrangement code generated by the calculation unit 13 is stored in advance as a database. In particular, in this embodiment, the storage device 21 stores the position and orientation of the current as a current pattern. The search unit 14 searches the database in the storage device 21 based on the search sequence code generated by the calculation unit 13 and specifies the current pattern (current position and orientation) in the composite distribution diagram. The output device 22 is configured by a liquid crystal display, for example, and displays the position and direction of the current specified by the search unit 14.

FIG. 2 is a diagram showing the concept of the horizontal component and the vertical component of the near magnetic field input to the magnetic field distribution diagram combining unit 11 from the input device 1 in FIG.
As shown in FIG. 2, a magnetic field probe 32 (magnetic field detection means) detects a near magnetic field with respect to a housing surface or a component mounting board surface of an object to be measured such as an electronic device 31. When the X and Y axes are taken in the horizontal direction with respect to the object, and the Z axis is taken in the vertical direction, it is composed of horizontal components Hx and Hy and a vertical component Hz.

FIG. 3 is a flowchart for explaining the operation of the near magnetic field measuring apparatus of FIG. 1, FIG. 4 is a diagram for explaining an example of the near magnetic field intensity distribution when a current is flowing through the wiring of the component mounting board, and FIG. FIG. 6 is a diagram for explaining processing performed by the array code extraction unit 12, and FIG. 7 is an example of a database stored in the storage device 21. FIG. And FIG. 8 are diagrams illustrating an example of a database stored in the storage device 21.
With reference to these drawings, the processing contents of the current pattern specifying method used in the near magnetic field measuring apparatus of this embodiment will be described.
In this near magnetic field measurement device, the magnetic field distribution diagram combining unit 11 extracts a portion where the maximum value of the magnetic field strength exists based on the strength distribution of the horizontal component and the vertical component of the near magnetic field input from the input device 1, The combined distribution map is generated (magnetic field distribution map combining process). In this magnetic field distribution map composition processing, the magnetic field distribution map composition unit 11 extracts from the local maximum value of the magnetic field strength to a level 3 dB lower than the local maximum value, and there is a region where the maximum values of the horizontal component and the vertical component of the magnetic field exist. A combined distribution map is generated by separating and combining so as not to overlap.

  The array code extraction unit 12 scans the combined distribution map generated by the magnetic field distribution map combining unit 11 in the vertical direction and the horizontal direction, and arranges the regions where the maximum values of the horizontal component and the vertical component of the magnetic field exist. The sequence code representing the current state is extracted (sequence code extraction process). In this arrangement code extraction process, the arrangement code extraction unit 12 scans the composite distribution chart in the vertical direction and the horizontal direction, and detects three or more regions where the maximum values of the horizontal component and the vertical component of the magnetic field exist. In some cases, it is extracted as a sequence code. The arithmetic unit 13 compares the magnetic field strengths of a plurality of vertical components that are elements of the sequence code with respect to a specific sequence code among the sequence codes extracted by the sequence code extraction unit 12, and the comparison result is A search sequence code is generated in addition to the sequence code (arithmetic processing).

  In this calculation process, when the arrangement code extracted by the arrangement code extraction unit 12 is composed of, for example, two horizontal components and three vertical components, and the vertical components and the horizontal components are alternately arranged, When the intensity of the magnetic field of the central vertical component is stronger than the vertical component at both ends, the comparison result shows that the currents corresponding to the two horizontal components are in the opposite directions, while the calculation unit 13 is in the vertical direction at both ends. When the intensity of the magnetic field of the central vertical component is weaker than that of the component, the above comparison results indicate that the currents corresponding to the two horizontal components are in the same direction. In the storage device 21, a current pattern corresponding to the search array code generated by the calculation unit 13 is stored in advance (storage processing). In this storage process, the storage device 21 stores the current position and orientation as a current pattern corresponding to the search array code. The search unit 14 searches the database of the storage device 21 based on the search sequence code generated by the calculation unit 13 and specifies the current pattern (current position and direction) in the composite distribution diagram (search processing). ).

  That is, as shown in FIG. 3, the intensity distribution data of the horizontal components Hx and Hy and the vertical component Hz of the near magnetic field detected by the magnetic field probe 32 with respect to the housing surface and the component mounting substrate surface of the electronic device are analyzed system 10. (Step A1). The magnetic field distribution map synthesis unit 11 generates a composite distribution map of the horizontal component Hx and the vertical component Hz using the intensity distribution data of the horizontal component Hx and the vertical component Hz of the input magnetic field (step A2). That is, as shown in FIG. 4A (wiring cross-sectional view), when a current is flowing through the wiring of the component mounting board, when a current is flowing in the y direction, a magnetic field is generated in the direction in which the right screw rotates. As shown in FIG. 4B (Hx distribution diagram), the magnetic field component Hx in the x direction has a region with a large magnetic field strength in the y direction along the wiring.

  Further, as shown in FIG. 4C (Hz distribution diagram), the vertical component Hz in the direction perpendicular to the wiring board has a distribution with regions having a large magnetic field strength on both sides of the wiring. In FIG. 4D, the magnetic field intensity on the line A-Ab in FIGS. 4B and 4C is plotted. When a combined distribution diagram of the horizontal component Hx and the vertical component Hz is created based on these data, there is a region where the horizontal component Hx and the vertical component Hz overlap as shown in FIG. If this overlapping area exists, the processing by the sequence code extraction unit 12 is inconvenient. For this reason, the magnetic field distribution diagram combining unit 11 performs processing so that the distributions of the horizontal component Hx and the vertical component Hz do not overlap.

  In this case, as shown in FIG. 5A, the magnetic field strength data of the horizontal component Hx and the vertical component Hz in FIG. FIG. 5B shows data extracted from the maximum value of the magnetic field strength | H | to the level 3 dB lower than the maximum value in the magnetic field strength data of FIG. In this way, by extracting a part of the data, overlap between the horizontal component Hx and the vertical component Hz is avoided. The maximum value can be obtained from the condition that the differentiation with respect to the position x of the magnetic field strength data is zero. By performing such processing on all data, as shown in FIG. 5C, a combined distribution diagram of the horizontal component Hx and the vertical component Hz without overlap is generated. In FIG. 5C, a region with a large magnetic field intensity is displayed in gradation.

  Subsequently, as shown in FIG. 3, the sequence code is extracted from the composite distribution map by the sequence code extraction unit 12 (step A3). In this case, as shown in FIG. 6A, with respect to the combined distribution diagram obtained by combining the magnetic field intensity distributions of the horizontal component Hx and the vertical component Hz, scanning is performed in the x direction at equal intervals from the scanning line sl1 to the scanning line sl7. When three or more regions having a large magnetic field strength, such as codes a, b, and c, are detected, an array code is obtained. For example, the number of locations where a high magnetic field strength is detected is limited to five, and the array code is an array code (a, b, c, d, e) using five elements of codes a to e. In FIG. 6A, an array code is obtained from the scanning lines sl2 to sl6. Since the codes a, b, and c correspond to regions where the vertical component Hz, horizontal component Hx, and vertical component Hz have high magnetic field strengths, the array codes (a, b, c, d, e) are array codes ( Z, X, Z, 0, 0). When the number of areas where the magnetic field strength is detected is less than five, the remaining elements are set to zero (“0”). In this example, since three locations are detected, the codes d and e are both “0”.

  In the arithmetic unit 13, when the array code extracted by the array code extraction unit 12 is (Z, X, Z, X, Z), the magnetic field strengths of the elements a and e and the element c are compared, and the array code is added. (A, b, c, d, e, P) (step A4). That is, it is determined whether or not the array code is (a, b, c, d, e) = (Z, X, Z, X, Z). The magnetic field strength with c is compared. This process has two types of magnetic field composite distribution diagrams in which the array code is (Z, X, Z, X, Z), and is performed for distinction. When the array code is (a, b, c, d, e) ≠ (Z, X, Z, X, Z), an element P is added to the array code (a, b, c, d, e, As “P”, “0” is substituted into P to become (a, b, c, d, e, 0).

  For example, when the array code input to the calculation unit 13 is (Z, X, X, Z, 0), it is (Z, X, X, Z, 0, 0). When the array code is (a, b, c, d, e) = (Z, X, Z, X, Z), and the magnetic field strength of the vertical component Hz of the element c is larger than the vertical component Hz of the element a, e. Becomes (Z, X, Z, X, Z, 1) by substituting “1” into the element P. When the vertical component Hz of the elements a and e is larger than the element c, “0” is substituted for the element P to be (Z, X, Z, X, Z, 0). In this way, the operation unit 13 generates an array code (a, b, c, d, e, P) to which the element P is added.

  Subsequently, the search unit 14 searches the database in the storage device 21 for the array code (a, b, c, d, e, P), and specifies the noise current pattern (step A5). For example, as shown in FIG. 7, the database has four array codes consisting of patterns 1X, 2X, 3X, and 4X, and the positions and directions of currents corresponding to the array codes are shown. In addition, a composite distribution diagram of the horizontal component Hx and the vertical component Hz and information on the intensity of the vertical component Hz are also shown. For example, the array code (a, b, c, d, e, P) = (Z, X, Z, X, Z, 1) is represented by the horizontal component Hx and the vertical component Hz in the pattern 1X in FIG. In the composite distribution diagram, in a region where the magnetic field strength is large, a vertical component Hz, a horizontal component Hx, a vertical component Hz, a horizontal component Hx, and a vertical component Hz are sequentially arranged in the X direction. Further, since the element P = 1, the intensity of the vertical component Hz of the vertical component Hz of the element c is larger than that of the elements a and e. The position and direction of the current that generates such a magnetic field distribution flows to a position immediately below the horizontal component Hx region corresponding to the element b and the element d in the combined distribution diagram of the horizontal component Hx and the vertical component Hz. For element d, the current is in the opposite direction.

  In addition, the array code (a, b, c, d, e, P) = (Z, X, X, Z, 0, 0) is the difference between the horizontal component Hx and the vertical component Hz in the pattern 2X in FIG. In the composite distribution diagram, in a region where the magnetic field strength is large, a vertical component Hz, a horizontal component Hx, a horizontal component Hx, and a vertical component Hz are sequentially arranged in the X direction. The position and direction of the current that generates such a magnetic field distribution flows to a position immediately below the region of the horizontal component Hx corresponding to the element b and the element c in the combined distribution diagram of the horizontal component Hx and the vertical component Hz. And the element c have the same current in the same direction.

  In addition, the array code (a, b, c, d, e, P) = (Z, X, Z, X, Z, 0) is the difference between the horizontal component Hx and the vertical component Hz in the pattern 3X in FIG. In the composite distribution diagram, a region with a large magnetic field strength is arranged in the same direction as the pattern 1X, in which the vertical component Hz, the horizontal component Hx, the vertical component Hz, the horizontal component Hx, and the vertical component Hz are sequentially arranged in the X direction. . However, the intensity of the vertical component Hz is smaller in the element c than in the elements a and e. The position and direction of the current that generates such a magnetic field distribution flows to a position immediately below the region of the horizontal component Hx corresponding to the element b and the element d in the combined distribution diagram of the horizontal component Hx and the vertical component Hz. And the element d have different currents in the same direction.

In addition, the array code (a, b, c, d, e, P) = (Z, X, Z, 0, 0, 0) is the difference between the horizontal component Hx and the vertical component Hz in the pattern 4X in FIG. In the composite distribution diagram, a vertical component Hz, a horizontal component Hx, and a vertical component Hz are sequentially arranged in the X direction in a region having a large magnetic field strength. The position and direction of the current that creates such a magnetic field distribution flows to a position immediately below the region of the horizontal component Hx corresponding to the element b in the combined distribution diagram of the horizontal component Hx and the vertical component Hz.
Thus, by searching the database of the storage device 21 by the search unit 14, the pattern of the noise current, such as the position and direction of the current that generates a magnetic field from the array code, is specified.

  In addition, the magnetic field distribution diagram combining unit 11 uses, for example, the intensity distribution data of the horizontal component Hy and the vertical component Hz of the input magnetic field, as in the case of the horizontal component Hx, a level lower by, for example, 3 dB from the maximum value of the data. From the extracted data, a combined distribution diagram of the horizontal component Hy and the vertical component Hz is generated (step B2). Subsequently, as shown in FIG. 3, the sequence code is extracted from the composite distribution map by the sequence code extraction unit 12 (step B3). In this case, as shown in FIG. 6B, the composite distribution diagram obtained by combining the magnetic field intensity distributions of the horizontal component Hy and the vertical component Hz is scanned in the y direction at equal intervals from the scanning line ml1 to the scanning line ml7. And three or more regions with a large magnetic field strength, such as codes a, b, and c, are detected as an array code. For example, the number of locations where a high magnetic field strength is detected is limited to five, and the array code is an array code (a, b, c, d, e) using five elements of codes a to e. In FIG. 6B, an array code is obtained from the scanning line ml2 to the scanning line ml6. Since codes a, b, and c correspond to regions where the magnetic field strength of vertical component Hz, horizontal component Hy, and vertical component Hz is large, array code (a, b, c, d, e) is array code ( Z, Y, Z, 0, 0). If there are less than five areas where the magnetic field intensity is detected, the remaining elements are set to zero (“0”). In this example, since three locations are detected, the codes d and e are both “0”.

  In the operation unit 13, in the case of the array code (Z, Y, Z, Y, Z) extracted by the array code extraction unit 12, the magnetic field strengths of the elements a and e and the element c are compared, and the array code is added. (A, b, c, d, e, P) (step B4). That is, it is determined whether or not the array code is (a, b, c, d, e) = (Z, Y, Z, Y, Z). The magnetic field strength with element c is compared. When the array code is (a, b, c, d, e) ≠ (Z, Y, Z, Y, Z), an element P is added to the array code (a, b, c, d, e, “0” is assigned to element P as (P), and (a, b, c, d, e, 0) is obtained.

  For example, when the array code input to the calculation unit 13 is (Z, Y, Y, Z, 0), it is (Z, Y, Y, Z, 0, 0). When the array code is (a, b, c, d, e) = (Z, Y, Z, Y, Z) and the magnetic field strength of the vertical component Hz of the element c is larger than the vertical component Hz of the element a, e. Becomes (Z, Y, Z, Y, Z, 1) by substituting “1” into the element P. When the vertical component Hz of the elements a and e is larger than the element c, “0” is substituted into the element P to be (Z, Y, Z, Y, Z, 0). In this way, the operation unit 13 generates an array code (a, b, c, d, e, P) to which the element P is added.

  Subsequently, the search unit 14 searches the database of the storage device 21 for the array code (a, b, c, d, e, P), and specifies the noise current pattern (step B5). For example, as shown in FIG. 8, the database has four array codes consisting of patterns 1Y, 2Y, 3Y, and 4Y, and the position and direction of current corresponding to each array code are shown. Further, a combined distribution diagram of the horizontal component Hy and the vertical component Hz and information on the intensity of the vertical component Hz are also shown. For example, the array code (a, b, c, d, e, P) = (Z, Y, Z, Y, Z, 1) is represented by the horizontal component Hy and the vertical component Hz in the pattern 1Y in FIG. In the composite distribution diagram, a vertical component Hz, a horizontal component Hy, a vertical component Hz, a horizontal component Hy, and a vertical component Hz are sequentially arranged in the Y direction in a region having a large magnetic field strength. Further, since the element P = 1, the intensity of the vertical component Hz of the vertical component Hz of the element c is larger than that of the elements a and e. The position and direction of the current that creates such a magnetic field distribution flows to a position immediately below the horizontal component Hy region corresponding to the element b and the element d in the combined distribution diagram of the horizontal component Hy and the vertical component Hz. In element d, the current is in the opposite direction.

  In addition, the array code (a, b, c, d, e, P) = (Z, Y, Y, Z, 0, 0) is the difference between the horizontal component Hy and the vertical component Hz in the pattern 2Y in FIG. In the composite distribution diagram, in a region where the magnetic field strength is large, a vertical component Hz, a horizontal component Hy, a horizontal component Hy, and a vertical component Hz are sequentially arranged in the Y direction. The position and direction of the current that generates such a magnetic field distribution flows to a position immediately below the region of the horizontal component Hy corresponding to the element b and the element c in the combined distribution diagram of the horizontal component Hy and the vertical component Hz. And the element c have the same current in the same direction.

  In addition, the array code (a, b, c, d, e, P) = (Z, Y, Z, Y, Z, 0) is the difference between the horizontal component Hy and the vertical component Hz in the pattern 3Y in FIG. In the composite distribution diagram, a region having a large magnetic field strength is arranged in the same manner as the pattern 1Y in which the vertical component Hz, the horizontal component Hy, the vertical component Hz, the horizontal component Hy, and the vertical component Hz are sequentially arranged in the Y direction. . However, the intensity of the vertical component Hz is smaller in the element c than in the elements a and e. The position and direction of the current that creates such a magnetic field distribution flows to a position immediately below the region of the horizontal component Hy corresponding to the element b and the element d in the combined distribution diagram of the horizontal component Hy and the vertical component Hz. And the element d have different currents in the same direction.

In addition, the array code (a, b, c, d, e, P) = (Z, Y, Z, 0, 0, 0) is the difference between the horizontal component Hy and the vertical component Hz in the pattern 4Y in FIG. In the composite distribution diagram, a vertical component Hz, a horizontal component Hy, and a vertical component Hz are sequentially arranged in the Y direction in a region having a large magnetic field strength. The position and direction of the current that creates such a magnetic field distribution flows to a position immediately below the region of the horizontal component Hy corresponding to the element b in the combined distribution diagram of the horizontal component Hy and the vertical component Hz.
Thus, by searching the database of the storage device 21 by the search unit 14, the pattern of the noise current, such as the position and direction of the current that generates a magnetic field from the array code, is specified. Then, information corresponding to the position and orientation of the noise current obtained in step A5 and step B5 in FIG. 3 is sent to the output device 22, and a photograph of the object to be measured corresponding to the composite distribution diagram or the magnetic field distribution measurement range, On the drawing, an arrow or the like corresponding to the information is superimposed and displayed (step A6).

  As described above, in this embodiment, the magnetic field distribution map combining unit 11 separates and combines the regions where the maximum values of the intensity of the horizontal component and the vertical component of the magnetic field do not overlap to generate a combined distribution map. An array code representing a state in which the region in which the maximum values of the horizontal component and the vertical component of the magnetic field are present is arranged is generated by the array code extraction unit 12 being scanned in the vertical direction and the horizontal direction by the array code extraction unit 12. Extracted. The arithmetic unit 13 compares the magnetic field strengths of a plurality of vertical components that are elements of the sequence code with respect to a specific sequence code among the sequence codes extracted by the sequence code extraction unit 12, and the comparison result is A search sequence code is generated in addition to the sequence code. The search unit 14 searches the database of the storage device 21 based on the search sequence code generated by the calculation unit 13 and specifies the current pattern (current position and orientation) in the composite distribution diagram. Thereby, the noise current which becomes a generation source of the unnecessary electromagnetic wave radiated | emitted from an electronic device etc. is specified.

  In addition, by specifying the position and direction of the noise current, it is possible to estimate the mechanism by which the electromagnetic interference is radiated and which circuit design should be reviewed. It can be seen where the magnetic sheet should be applied. In addition, since the position and orientation of the noise current can be automatically specified, product development efficiency and product cost reduction are realized. Further, the search array code generated by the arithmetic unit 13 includes a comparison result of the magnetic field strengths of a plurality of vertical components. The inconvenience that magnetic field distributions having different current patterns are represented by the same array code is avoided.

The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to the embodiment, and even if there is a design change without departing from the gist of the present invention, Included in the invention.
For example, in the above-described embodiment, the magnetic field distribution diagram combining unit 11 extracts from the maximum value of the magnetic field strength to a level 3 dB lower than the same maximum value, but is not limited to 3 dB. Further, the number of locations where the array code extraction unit 12 detects a region with a high magnetic field strength is not limited to five.

  A part or all of the above embodiment can be described as in the following supplementary notes, but is not limited to the following.

  (Supplementary note 1) Based on the intensity distribution of the horizontal and vertical components of the near magnetic field detected by the magnetic field detection means for a predetermined surface of the object to be measured, a portion where the maximum value of the magnetic field strength exists is extracted and synthesized Magnetic field distribution map synthesis means for generating a composite distribution map, and scanning the composite distribution map generated by the magnetic field distribution map synthesis means in the vertical and horizontal directions to determine the intensity of the horizontal and vertical components of the magnetic field. Sequence code extraction means for extracting a sequence code representing a state in which the region where the local maximum exists is arranged, and for a specific sequence code of the sequence code extracted by the sequence code extraction means, Comparing the magnetic field strengths of a plurality of vertical components that are elements of the array code, and adding the comparison result to the array code to generate a search array code; and for the search generated by the operation means Array code A storage unit in which a corresponding current pattern is stored in advance as a database, and the database is searched based on the search sequence code generated by the calculation unit, and a current pattern in the composite distribution diagram is specified. And a near magnetic field measuring device.

  (Additional remark 2) The said magnetic field distribution map synthetic | combination means extracts from the maximum value of the said magnetic field intensity to the predetermined level lower than this maximum value, and the area | region where the said local maximum value of the horizontal component of a magnetic field and the intensity | strength of a perpendicular component exists overlaps. The near magnetic field measuring apparatus according to appendix 1, wherein the combined distribution map is generated by separating and combining so as not to match.

  (Supplementary note 3) The near-field magnetic field measurement apparatus according to supplementary note 1 or 2, wherein the magnetic field distribution diagram combining means extracts a maximum value of the magnetic field intensity from a maximum value to a level 3 dB lower than the maximum value.

  (Additional remark 4) The said arrangement | sequence code extraction means scanned the said synthetic | combination distribution chart to the vertical direction and the horizontal direction, and the area | region where the said local maximum value of the intensity | strength of the horizontal component of a magnetic field and a perpendicular | vertical component exists was detected three or more places. 4. The near magnetic field measurement apparatus according to appendix 1, 2, or 3, wherein the arrangement code is extracted in some cases.

  (Supplementary Note 5) In the calculation means, the array code extracted by the array code extraction means is composed of at least two horizontal components and three vertical components, and the vertical components and the horizontal components are alternated. When the intensity of the magnetic field of the vertical component at the center is stronger than the vertical component at both ends, the comparison result is obtained when the currents corresponding to the two horizontal components are in the opposite directions to each other. On the other hand, when the strength of the magnetic field of the vertical component at the center is weaker than the vertical component at both ends, the comparison result is configured such that the currents corresponding to the two horizontal components are in the same direction. The near magnetic field measuring apparatus according to appendix 1, 2, 3 or 4.

  (Supplementary note 6) The near magnetic field measurement device according to supplementary note 1, 2, 3, 4 or 5, wherein the storage means stores the position and orientation of the current as the pattern of the current corresponding to the search arrangement code. .

  (Supplementary note 7) The near magnetic field measurement apparatus according to supplementary note 6, wherein the search means is configured to search the database and specify a position and direction of a current in the composite distribution diagram.

  (Supplementary note 8) The magnetic field distribution diagram combining means has a maximum value of the magnetic field strength based on the intensity distribution of the horizontal component and the vertical component of the near magnetic field detected by the magnetic field detecting unit with respect to a predetermined surface of the object to be measured. A magnetic field distribution diagram synthesis process for extracting a portion to be combined and generating a composite distribution diagram, and an array code extraction unit scans the composite distribution diagram generated by the magnetic field distribution diagram synthesis unit in a vertical direction and a horizontal direction Then, an array code extraction process for extracting an array code representing a state in which regions where the maximum values of the horizontal component and the vertical component of the magnetic field exist are arranged, and an operation unit extracts the sequence code by the array code extraction unit Compared to a specific sequence code of the sequence codes, the strengths of magnetic fields of a plurality of vertical components that are elements of the sequence code are added, and the comparison result is added to the sequence code. Generate a A storage process in which the storage unit stores in advance a current pattern corresponding to the search array code generated by the calculation unit as a database, and a search unit is used for the search generated by the calculation unit. A current pattern specifying method for searching the database based on an array code and performing a search process for specifying a current pattern in the composite distribution map.

  (Supplementary Note 9) In the magnetic field distribution map synthesis process, the magnetic field distribution map synthesis means extracts from the maximum value of the magnetic field strength to a predetermined level lower than the maximum value, and calculates the intensity of the horizontal component and the vertical component of the magnetic field. The current pattern specifying method according to appendix 8, wherein the combined distribution map is generated by separating and combining so that regions where local maximum values exist do not overlap.

  (Supplementary note 10) The current pattern specifying method according to supplementary note 8 or 9, wherein, in the magnetic field distribution map synthesis process, the magnetic field distribution map synthesis means extracts from a maximum value of the magnetic field strength to a level 3 dB lower than the maximum value.

  (Supplementary Note 11) In the array code extraction process, the array code extraction unit scans the combined distribution diagram in the vertical direction and the horizontal direction, and the region where the maximum values of the horizontal component and the vertical component of the magnetic field exist is present. 11. The current pattern specifying method according to appendix 8, 9 or 10, wherein when three or more points are detected, the arrangement code is extracted.

  (Additional remark 12) In the said arithmetic processing, the said arrangement | sequence code extracted by the said arrangement | sequence code extraction means consists of at least two said horizontal components and three said vertical components, and the said vertical component and the said horizontal component alternate When the calculation means has a stronger magnetic field intensity of the vertical component at the center than the vertical components at both ends, the comparison results indicate that the currents corresponding to the two horizontal components are equal to each other. On the other hand, when the strength of the magnetic field of the vertical component at the center is weaker than the vertical component at both ends, the comparison results are obtained by setting the currents corresponding to the two horizontal components in the same direction. The current pattern specifying method according to appendix 8, 9, 10 or 11, which is configured.

  (Additional remark 13) In the said memory | storage process, the said memory | storage means memorize | stores the position and direction of the said electric current as said pattern of the electric current corresponding to the said arrangement | sequence code for a search, The electric current of Additional remark 8, 9, 10, 11 or 12 Pattern identification method.

  (Additional remark 14) In the said search process, the said search means searches the said database based on the said sequence code for a search produced | generated by the said calculating means, and specifies the position and direction of an electric current in the said synthetic distribution map. 14. The current pattern specifying method according to 13.

  (Additional remark 15) The current pattern specific program which makes a computer function as a near magnetic field measuring apparatus as described in any one of additional marks 1 thru | or 7.

  The present invention can be applied to all near-field magnetic field measuring devices that specify noise current, such as electronic devices and integrated circuits.

11 Magnetic field distribution diagram synthesis unit (magnetic field distribution diagram synthesis means)
12 Sequence code extraction unit (sequence code extraction means)
13 Calculation unit (calculation means)
14 Search part (search means)
21 Storage device (storage means)

Claims (10)

Based on the intensity distribution of the horizontal and vertical components of the near magnetic field detected by the magnetic field detection means for a predetermined surface of the object to be measured, the portion where the maximum value of the magnetic field strength exists is extracted and combined to obtain a combined distribution Magnetic field distribution diagram synthesis means for generating a diagram;
The combined distribution map generated by the magnetic field distribution map combining means is scanned in the vertical and horizontal directions to represent a state in which regions where the maximum values of the horizontal component and vertical component of the magnetic field exist are arranged. Sequence code extraction means for extracting the sequence code;
The strength of the magnetic field of a plurality of vertical components that are elements of the sequence code is compared with a specific sequence code among the sequence codes extracted by the sequence code extraction means, and the comparison result is stored in the sequence code. A computing means for generating a sequence code for search by adding;
Storage means in which a current pattern corresponding to the search sequence code generated by the calculation means is stored in advance as a database;
A near magnetic field measuring apparatus comprising: search means for searching the database based on the search arrangement code generated by the calculation means and specifying a current pattern in the composite distribution map. The magnetic field distribution map synthesis means includes:
Extracting from the local maximum value of the magnetic field strength to a predetermined level lower than the local maximum value, separating and synthesizing the regions where the local maximum value of the horizontal component and the vertical component of the magnetic field exist so as not to overlap. The near magnetic field measuring apparatus according to claim 1, wherein the near field magnetic field measuring apparatus is configured to generate a distribution map. The magnetic field distribution map synthesis means includes:
3. The near magnetic field measuring apparatus according to claim 1, wherein the magnetic field intensity is extracted from a maximum value of the magnetic field strength to a level 3 dB lower than the maximum value. The sequence code extracting means includes
The composite distribution diagram is scanned in the vertical direction and the horizontal direction, and is extracted as the array code when three or more regions where the maximum values of the horizontal component and the vertical component of the magnetic field exist are detected. The near magnetic field measuring apparatus according to claim 1, 2 or 3. The computing means is
When the arrangement code extracted by the arrangement code extraction means is composed of at least two horizontal components and three vertical components, and the vertical components and the horizontal components are alternately arranged, When the intensity of the magnetic field of the vertical component at the center is stronger than that of the vertical component at both ends, the comparison results indicate that the currents corresponding to the two horizontal components are in opposite directions, whereas the vertical components at both ends 2, wherein when the intensity of the magnetic field of the vertical component at the center is weak, the comparison result is configured such that currents corresponding to the two horizontal components are in the same direction. The near magnetic field measuring apparatus according to 2, 3 or 4. The storage means
6. The near magnetic field measurement apparatus according to claim 1, wherein the current position and direction are stored as the current pattern corresponding to the search sequence code. The search means includes
The near magnetic field measuring apparatus according to claim 6, wherein the database is searched and a position and direction of a current are specified in the composite distribution map. The magnetic field distribution diagram combining means extracts a portion where the maximum value of the magnetic field strength exists based on the intensity distribution of the horizontal component and the vertical component of the near magnetic field detected by the magnetic field detection means with respect to a predetermined surface of the object to be measured. Magnetic field distribution map synthesis processing for generating a composite distribution map by combining,
An array code extracting unit scans the combined distribution map generated by the magnetic field distribution map combining unit in a vertical direction and a horizontal direction, and an area where the maximum values of the horizontal component and the vertical component of the magnetic field exist is arranged. A sequence code extraction process for extracting a sequence code representing the state being performed;
The arithmetic means compares the magnetic field strengths of a plurality of vertical components that are elements of the array code with respect to a specific array code of the array codes extracted by the array code extraction means, and the comparison result is obtained. A calculation process for generating a search sequence code in addition to the sequence code;
A storage process in which a storage unit stores in advance, as a database, a current pattern corresponding to the search array code generated by the calculation unit;
A current pattern specification characterized in that a search means searches the database based on the search sequence code generated by the calculation means and performs a search process for specifying a current pattern in the composite distribution map. Method. In the magnetic field distribution map synthesis process,
The magnetic field distribution diagram combining means extracts from the maximum value of the magnetic field strength to a predetermined level lower than the maximum value so that the regions where the maximum values of the horizontal component and the vertical component of the magnetic field exist do not overlap. 9. The current pattern specifying method according to claim 8, wherein the combined distribution map is generated by separating and combining. In the magnetic field distribution map synthesis process,
10. The current pattern specifying method according to claim 8, wherein the magnetic field distribution diagram combining means extracts the maximum value of the magnetic field intensity from the maximum value to a level 3 dB lower than the maximum value.

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