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| Title: | Estimating maximum radiated emissions from printed circuit boards with an attached cable | |
| Author (s): | Deng, Shaowei Hubing, Todd H. Beetner, Daryl G. | |
| Department/Lab Affiliations: | Electrical and Computer Engineering Electromagnetic Compatibility Laboratory | |
| Keywords: | Antenna model PCB cable cables (electric) closed-form equation common-mode current electromagnetic interference equivalent voltage source maximum radiated emissions peak full-wave simulation printed circuit board (PCB) printed circuits radiated emission testing | |
| Issue Date: | 2008-02 | |
| Publisher: | Institute of Electrical and Electronics Engineers IEEE | |
| Citation: | S. Deng, T. Hubing, and D. Beetner. Estimating Maximum Radiated Emissions from Printed Circuit Boards with an Attached Cable, IEEE Transactions on Electromagnetic Compatibility, vol. 50(1), pp. 215-218, 2008. | |
| Abstract: | The common-mode current induced on cables attached to printed circuit boards can be a significant source of radiated emissions. Previous studies have shown that coupling from electric and magnetic field sources on circuit boards can be effectively modeled by placing equivalent voltage sources between the board and the cable. The amplitude of these equivalent sources can be estimated by using closed-form equations; however, estimates of the radiated emissions from these board-cable geometries have required full-wave simulations, and full-wave simulation results depend on the exact cable length and placement, which are not normally fixed during radiated emissions testing. This paper develops a closed-form equation to estimate the maximum radiated fields from a voltage source driving a board relative to an attached cable over a ground plane. This equation is evaluated for various cable and board geometries by comparing the calculated results to full-wave simulations. The maximum radiation calculated by using the closed-form expression generally predicts the peak full-wave simulation results within a few decibels for various board sizes and cable lengths. | |
| Type: | Article - Journal text | |
| In Title: | IEEE Transactions on Electromagnetic Compatibility | |
| Copyright Notice: | This material is presented to ensure timely dissemination of scholarly and technical work. Copyright and all rights therein are retained by authors or by other copyright holders. All persons copying this information are expected to adhere to the terms and constraints invoked by each author's copyright. In most cases, these works may not be reposted without the explicit permission of the copyright holder. allows publisher's final version to be uploaded FULL COPYRIGHT INFORMATION: | |
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| title | Estimating maximum radiated emissions from printed circuit boards with an attached cable | |
| contributor.author | Deng, Shaowei | |
| contributor.author | Hubing, Todd H. | |
| contributor.author | Beetner, Daryl G. | |
| contributor.deptlab | Electrical and Computer Engineering | |
| contributor.deptlab | Electromagnetic Compatibility Laboratory | |
| subject | Antenna model | |
| subject | PCB cable | |
| subject | cables (electric) | |
| subject | closed-form equation | |
| subject | common-mode current | |
| subject | electromagnetic interference | |
| subject | equivalent voltage source | |
| subject | maximum radiated emissions | |
| subject | peak full-wave simulation | |
| subject | printed circuit board (PCB) | |
| subject | printed circuits | |
| subject | radiated emission testing | |
| date.issued | 2008-02 | |
| publisher | Institute of Electrical and Electronics Engineers IEEE | |
| identifier.citation | S. Deng, T. Hubing, and D. Beetner. Estimating Maximum Radiated Emissions from Printed Circuit Boards with an Attached Cable, IEEE Transactions on Electromagnetic Compatibility, vol. 50(1), pp. 215-218, 2008. | |
| identifier.pub.URI | ||
| description.abstract | The common-mode current induced on cables attached to printed circuit boards can be a significant source of radiated emissions. Previous studies have shown that coupling from electric and magnetic field sources on circuit boards can be effectively modeled by placing equivalent voltage sources between the board and the cable. The amplitude of these equivalent sources can be estimated by using closed-form equations; however, estimates of the radiated emissions from these board-cable geometries have required full-wave simulations, and full-wave simulation results depend on the exact cable length and placement, which are not normally fixed during radiated emissions testing. This paper develops a closed-form equation to estimate the maximum radiated fields from a voltage source driving a board relative to an attached cable over a ground plane. This equation is evaluated for various cable and board geometries by comparing the calculated results to full-wave simulations. The maximum radiation calculated by using the closed-form expression generally predicts the peak full-wave simulation results within a few decibels for various board sizes and cable lengths. | |
| type | Article - Journal | |
| type.DCMIType | text | |
| type.status | Final version | |
| rights | This material is presented to ensure timely dissemination of scholarly and technical work. Copyright and all rights therein are retained by authors or by other copyright holders. All persons copying this information are expected to adhere to the terms and constraints invoked by each author's copyright. In most cases, these works may not be reposted without the explicit permission of the copyright holder. | |
| rights | allows publisher's final version to be uploaded | |
| rights.URI | ||
| rights.URI | ||
| rights.URI | ||
| relation.isPartOf | IEEE Transactions on Electromagnetic Compatibility | |
| date.accessioned | 2008-06-23T18:30:10Z | |
| date.available | 2008-06-24T19:52:26Z | |
| identifier.persist.URI | ||
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