Design for Miniature Filter with Ultra-wide Stopband Based on Open-Stub T-shaped Structure

Zhu  Yi-Zhi; Zhang  Xiao-Juan; Fang Guang-You

doi:10.3724/SP.J.1146.2009.01021

Volume 32 Issue 9

Oct. 2010

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Article Navigation > Journal of Electronics & Information Technology > 2010 > 32(9): 2282-2286

Zhu Yi-Zhi, Zhang Xiao-Juan, Fang Guang-You. Design for Miniature Filter with Ultra-wide Stopband Based on Open-Stub T-shaped Structure[J]. Journal of Electronics & Information Technology, 2010, 32(9): 2282-2286. doi: 10.3724/SP.J.1146.2009.01021

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Zhu Yi-Zhi, Zhang Xiao-Juan, Fang Guang-You. Design for Miniature Filter with Ultra-wide Stopband Based on Open-Stub T-shaped Structure[J]. Journal of Electronics & Information Technology, 2010, 32(9): 2282-2286. doi: 10.3724/SP.J.1146.2009.01021

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Design for Miniature Filter with Ultra-wide Stopband Based on Open-Stub T-shaped Structure

doi: 10.3724/SP.J.1146.2009.01021

Received Date: 2009-07-17
Rev Recd Date: 2010-01-18
Publish Date: 2010-09-19

Abstract

Abstract

Conventional filters always suffer from the interference of its spurious bands, which leads to poor stopband in high frequency range. With the development of ultra-wide band radar system and ultra-wide band communication system, filters with minitype and wide-stopband become an urgent technique challenge. In this paper, a general design of miniature filter with ultra-wide stopband based on open-stub T-shaped structure is demonstrated. Comparing with conventional filters, this type of filters have compact structure, good passband characteristics and its spurious bands whtiin the fifth order harmonic frequency range are all suppressed. A lowpass filter with cutoff frequency at 2.9GHz is designed with the proposed structure. The measured average insertion loss is only 0.67dB, average VSWR is only 1.33. Its transition band is steep and its 40dB square ratio is 1.096. The measured 36dB stopband ranges from 3.23GHz to 10.30GHz and 27dB stopband ranges from 10.30GHz to 15GHz. Moreover, its length is only 37.1% of the conventional substitutional filter, with much less area and more compact layout. The simulated and measured results indicate that this open-stub T-shaped filter satisfies the demand of both minitype and wide-stopband.
- Miniature filter,
- Ultra-wide stopband,
- Open-stub T-shaped structure

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References(1)

References

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