Switchable Bandpass Filter for 0.3-0.6 GHz

Koochakzadeh, Masoud; Abbaspour-Tamijani, A.

doi:10.1109/mwsym.2007.380550

Cited by 12 publications

(8 citation statements)

References 9 publications

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“…The derived equation (13) shows that the rejection bandwidth is strongly dependent on the connecting stub length (u 1 ). This can also be confirmed by equations (8)- (11). This can also be confirmed by equations (8)- (11).…”

Section: C) Equivalent Circuit Modelssupporting

confidence: 78%

A switchable bandstop-to-bandpass reconfigurable filter for cognitive radio applications

Nachouane

Najid

Tribak

et al. 2016

Int. J. Microw. Wireless Technol.

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A switchable bandstop-to-bandpass reconfigurable filter for cognitive radio applications hamza nachouane, abdellah najid, abdelwahed tribak and fatima riouch This paper presents a simple reconfigurable bandpass filter switching from 2.4 to 5 GHz based on PIN diodes. The proposed filter is intended to add frequency-tunability to antenna systems used in cognitive radio applications. It consists of a bent connecting stub with two open-circuited quarter-wave stubs grounded via PIN diodes. By controlling the didoes states, the electrical length of the stubs can be switched from quarter-wave to half-wave and vice versa, so as to tune the filter center frequency. The proposed design approach consists of ensuring communication at 2.4 GHz while blocking the 5 GHz band in the ON state, whereas in the OFF state, the filter is intended to reject the 2.4 GHz band and passing the 5 GHz band. A prototype of the proposed filter is fabricated and measured to validate the proposed concept. Both simulated and measured results show a two-state filter with a wide tuning range from 2.4 to 5 GHz and a good stopband rejection level better than 40 dB. Moreover, a flat group delay of about 0.55-0.7 ns is achieved within the operating bandwidth in both states. The proposed filter is able to achieve simultaneous bandwidth and frequency control, showing an important tool to meet modern system requirements.

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Section: C) Equivalent Circuit Modelssupporting

confidence: 78%

A switchable bandstop-to-bandpass reconfigurable filter for cognitive radio applications

Nachouane

Najid

Tribak

et al. 2016

Int. J. Microw. Wireless Technol.

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“…The 3 dB bandwidths are almost constant for all states. The insertion losses are 0.43, 0.47, 0.67 and 0.81 dB in the filter states (00), (01), (10) and (11), respectively, values that are lower than the filter values reported in [5,6]. The return losses are better than 17 dB in all states without tuning.…”

mentioning

confidence: 74%

“…Many switches and components, including MEMS filters [1], varactors [2], bonding wire [3], tuning screws [4] and pin diodes [5,6], are adopted to realise the frequency switching of filters in different bands. The MEMS filter is used to adjust the centre frequency of the filter and to ensure a large tuning range [1].…”

mentioning

confidence: 99%

“…Introduction: Switchable filters have been widely researched and used in engineering applications owing to their flexibility, compact size and frequency switching property [1][2][3][4][5][6]. Many switches and components, including MEMS filters [1], varactors [2], bonding wire [3], tuning screws [4] and pin diodes [5,6], are adopted to realise the frequency switching of filters in different bands.…”

mentioning

confidence: 99%

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UHF band switchable superconducting filter with pin diode switches

et al. 2014

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A low-loss switchable superconducting filter is presented. High Q resonators loaded with switchable superconducting interdigital capacitors are introduced. A two-pole 2-bit switchable high-temperature superconducting (HTS) filter at 516 MHz with a bandwidth of 29 MHz is designed and fabricated. The measured centre frequency tuning range is 33 MHz (6.4%). In all states, the HTS filter with pin diode switches exhibits an insertion loss <0.81 dB and a good return loss better than 16.8 dB.Introduction: Switchable filters have been widely researched and used in engineering applications owing to their flexibility, compact size and frequency switching property [1][2][3][4][5][6]. Many switches and components, including MEMS filters [1], varactors [2], bonding wire [3], tuning screws [4] and pin diodes [5,6], are adopted to realise the frequency switching of filters in different bands. The MEMS filter is used to adjust the centre frequency of the filter and to ensure a large tuning range [1]. The varactor is utilised to switch frequencies continuously [2]. Pin diodes have the advantages of small size and fast switching speed. However, traditional switchable filters have the disadvantages of a low Q-value resonator and high insertion loss [5,6]. A 14.7% fractional bandwidth filter with pin diodes for 9-11 GHz has a 1.76 dB insertion loss [5], whereas the switchable bandpass filter with pin diodes for 0.3-0.6 GHz has a 1.32-1.95 dB insertion loss and an 11-19 equivalent Q-value [6].High-temperature superconducting (HTS) thin films, which have very low surface resistance, are used to fabricate high-performance filters with low insertion loss and extraordinarily steep skirts [1,3,4,7]. An HTS filter switching frequency by bonding wire has a high Q-value resonator in all four states [3], but it cannot be used for practical applications because of its long switching time. The high-speed mechanical tuning system with screws and step motors for HTS filters is complex and requires the installation of numerous peripheral components [4].In this Letter, a new type of switchable HTS filter with pin diodes is proposed. The proposed filter combines the advantages of a high Q-value resonator and fast switching speed. The high Q-value resonator has a novel structure with interdigital capacitors (IDCs) at the two ends to connect switches, giving it the advantages of constant bandwidth and compact size. The frequency switching principle is discussed and analysed in detail in this Letter. The two-pole switchable HTS filter is fabricated on an MgO substrate with double-sided coated YBCO films. The measured results of the filter match well with the simulations.

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“…Then, the idea is to short-circuit the stepped-impedance stubs at the end of the inner quarter-wavelength portion, i.e. at the stepped-impedance transition, therefore, the first inner characteristic impedance can be determined by (18) using (14).…”

Section: Half-wavelength Open-circuited Stubs With Stepped-impedanmentioning

confidence: 99%

A Novel Synthesis for Bandwidth Switchable Bandpass Filters Using Semi-Conductor Distributed Doped Areas

et al. 2020

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This paper presents a novel synthesis for bandwidth switchable bandpass filters using Semiconductor Distributed Doped Areas (ScDDAs) as active elements. A co-design method is proposed with a global and simultaneous conception for the active and the passive parts of the switchable filters. The ScDDAs, integrated in the silicon substrate, are able to commute from half-wavelength open-ended stubs to quarter-wavelength short-circuited ones. This co-design method offers a great flexibility and allows to integrate the active elements directly in the substrate, therefore avoiding any soldering of components. The synthesis is developed for the two-states of the active elements and applied, as a proof of concept, to a fourpole bandwidth switchable bandpass filter. This filter operates at 5 GHz with a 50 % bandwidth in the OFFstate (when the stubs are terminated by an open-circuit) and with a 70 % bandwidth in the ON-state (when the stubs are short-circuited). For this filter, the synthesis is detailed in the two-states allowing to choose the two desired bandwidths. A good fitting is obtained for these results proving the viability of such an approach.

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Switchable Bandpass Filter for 0.3-0.6 GHz

Cited by 12 publications

References 9 publications

A switchable bandstop-to-bandpass reconfigurable filter for cognitive radio applications

A switchable bandstop-to-bandpass reconfigurable filter for cognitive radio applications

UHF band switchable superconducting filter with pin diode switches

A Novel Synthesis for Bandwidth Switchable Bandpass Filters Using Semi-Conductor Distributed Doped Areas

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