Conferences related to Noise Cancelling

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ICC 2021 - IEEE International Conference on Communications

IEEE ICC is one of the two flagship IEEE conferences in the field of communications; Montreal is to host this conference in 2021. Each annual IEEE ICC conference typically attracts approximately 1,500-2,000 attendees, and will present over 1,000 research works over its duration. As well as being an opportunity to share pioneering research ideas and developments, the conference is also an excellent networking and publicity event, giving the opportunity for businesses and clients to link together, and presenting the scope for companies to publicize themselves and their products among the leaders of communications industries from all over the world.


2020 22nd European Conference on Power Electronics and Applications (EPE'20 ECCE Europe)

Energy conversion and conditioning technologies, power electronics, adjustable speed drives and their applications, power electronics for smarter grid, energy efficiency,technologies for sustainable energy systems, converters and power supplies


2020 42nd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC)

The conference program will consist of plenary lectures, symposia, workshops and invitedsessions of the latest significant findings and developments in all the major fields of biomedical engineering.Submitted papers will be peer reviewed. Accepted high quality papers will be presented in oral and postersessions, will appear in the Conference Proceedings and will be indexed in PubMed/MEDLINE


2020 IEEE International Conference on Consumer Electronics (ICCE)

The International Conference on Consumer Electronics (ICCE) is soliciting technical papersfor oral and poster presentation at ICCE 2018. ICCE has a strong conference history coupledwith a tradition of attracting leading authors and delegates from around the world.Papers reporting new developments in all areas of consumer electronics are invited. Topics around the major theme will be the content ofspecial sessions and tutorials.


2020 IEEE International Solid- State Circuits Conference - (ISSCC)

ISSCC is the foremost global forum for solid-state circuits and systems-on-a-chip. The Conference offers 5 days of technical papers and educational events related to integrated circuits, including analog, digital, data converters, memory, RF, communications, imagers, medical and MEMS ICs.


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Periodicals related to Noise Cancelling

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Antennas and Propagation, IEEE Transactions on

Experimental and theoretical advances in antennas including design and development, and in the propagation of electromagnetic waves including scattering, diffraction and interaction with continuous media; and applications pertinent to antennas and propagation, such as remote sensing, applied optics, and millimeter and submillimeter wave techniques.


Applied Superconductivity, IEEE Transactions on

Contains articles on the applications and other relevant technology. Electronic applications include analog and digital circuits employing thin films and active devices such as Josephson junctions. Power applications include magnet design as well asmotors, generators, and power transmission


Automatic Control, IEEE Transactions on

The theory, design and application of Control Systems. It shall encompass components, and the integration of these components, as are necessary for the construction of such systems. The word `systems' as used herein shall be interpreted to include physical, biological, organizational and other entities and combinations thereof, which can be represented through a mathematical symbolism. The Field of Interest: shall ...


Biomedical Circuits and Systems, IEEE Transactions on

The Transactions on Biomedical Circuits and Systems addresses areas at the crossroads of Circuits and Systems and Life Sciences. The main emphasis is on microelectronic issues in a wide range of applications found in life sciences, physical sciences and engineering. The primary goal of the journal is to bridge the unique scientific and technical activities of the Circuits and Systems ...


Broadcasting, IEEE Transactions on

Broadcast technology, including devices, equipment, techniques, and systems related to broadcast technology, including the production, distribution, transmission, and propagation aspects.


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Most published Xplore authors for Noise Cancelling

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Xplore Articles related to Noise Cancelling

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Noise figure optimization of a noise-cancelling wide-band CMOS LNA

Proceedings of the 8th IEEE International NEWCAS Conference 2010, 2010

This paper discusses noise figure optimization techniques for a noise- cancelling single-ended-to-differential CMOS low-noise amplifier (LNA). In [1], a low noise figure was obtained through cancellation of the drain noise of the common-gate transistor. Contour plots demonstrate that drain noise cancellation does not guarantee an optimal noise figure. The optimal noise figure is achieved by minimizing the un-cancelled noise contributions ...


On the application of variable-step adaptive noise cancelling for improving the robustness of speech recognition

2009 ISECS International Colloquium on Computing, Communication, Control, and Management, 2009

As speech recognition and spoken language technologies are being transferred to real applications, the need for greater robustness against adverse noise is becoming increasingly apparent. This paper researches a robust speech recognition method based on adaptive noise cancelling (ANC). It obtained the enhanced speech signal by applying a variable-step adaptive noise cancelling algorithm to reduce noise as pre-treatment of speech ...


A Digital Phase Noise Cancelling Scheme for Ring Oscillator-based Fractional-N ADPLL

2018 IEEE International Symposium on Circuits and Systems (ISCAS), 2018

This paper presents a digital phase noise cancelling scheme for ring oscillator (RO)-based fractional-N ADPLL, which can suppress both in-band and out-of-band phase noise of RO. The scheme adopts a high-resolution time-to- digital convertor (TDC) to sample the rising edge timing errors between RO output and the reference signal (REF) and a matched digital-to-time convertor (DTC) to compensate these timing ...


A 1.3 V noise-cancelling low noise amplifier for ultra wideband applications

2016 IEEE 5th Global Conference on Consumer Electronics, 2016

An ultra wideband (UWB) noise-cancelling low-noise amplifier (NCLNA) is proposed in this paper. A common-gate input stage with an input matching network is implemented to make input resistance matching to 50-ohm. The power consumption of the presented NCLNA can be lower by using current-reuse architecture. A noise cancelling technique is adopted to decrease the noise generated by the first common-gate ...


A 6.3–6.8GHz LNA with noise cancelling and adjacent channel rejection for wideband mobile communication

2015 IEEE International Conference on Communication Problem-Solving (ICCP), 2015

This paper discusses a 6.3-6.8GHz single-ended-to-differential LNA with noise- cancelling and adjacent channel rejection for wideband mobile communication. Different from traditional noise-cancelling LNA, this circuit includes local feedback, current reuse and considering bond-wire effect. Besides, this design utilizes a couple of differential-to-single buffers to reduce the mismatch of the differential signal output from single-ended-to-differential LNA. Bond- wire inductance and ESD ...


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Educational Resources on Noise Cancelling

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IEEE.tv Videos

An FTNC Receiver with +32.5dBm Effective OB-IIP3 Using Baseband IM3 Cancellation: RFIC Interactive Forum 2017
IMS 2011 Microapps - A Comparison of Noise Parameter Measurement Techniques
Noise Enhanced Information Systems: Denoising Noisy Signals with Noise
IMS 2011 Microapps - Ultra Low Phase Noise Measurement Technique Using Innovative Optical Delay Lines
ISEC 2013 Special Gordon Donaldson Session: Remembering Gordon Donaldson - 7 of 7 - SQUID-based noise thermometers for sub-Kelvin thermometry
IMS 2012 Microapps - Phase Noise Choices in Signal Generation: Understanding Needs and Tradeoffs Riadh Said, Agilent
MicroApps: Phase Noise, Allan Variance, and Frequency Reference (Agilent Technologies)
IMS 2012 Special Sessions: The Evolution of Some Key Active and Passive Microwave Components - E. C. Niehenke
A Transformer-Based Inverted Complementary Cross-Coupled VCO with a 193.3dBc/Hz FoM and 13kHz 1/f3 Noise Corner: RFIC Interactive Forum
A 40GHz PLL with -92.5dBc/Hz In-Band Phase Noise and 104fs-RMS-Jitter: RFIC Interactive Forum 2017
Impact of Linearity and Write Noise of Analog Resistive Memory: IEEE Rebooting Computing 2017
An Analysis of Phase Noise Requirements for Ultra-Low-Power FSK Radios: RFIC Interactive Forum 2017
A Low Power High Performance PLL with Temperature Compensated VCO in 65nm CMOS: RFIC Interactive Forum
Noise-Shaped Active SAR Analog-to-Digital Converter - IEEE Circuits and Systems Society (CAS) Distinguished Lecture
Compact 75 GHz LNA with 20-dB Gain and 4-dB Noise Figure - Woorim Shin - RFIC Showcase 2018
IMS 2014: A 600 GHz Low-Noise Amplifier Module
Optical Stealth Communication based on Amplified Spontaneous Emission Noise - Ben Wu - IEEE Sarnoff Symposium, 2019
Non-Volatile Memory Array Based Quantization - Wen Ma - ICRC San Mateo, 2019
Transistors for THz Systems
IMS 2014: LNA Modules for the WR4 (170-260 GHz) Frequency Range

IEEE-USA E-Books

  • Noise figure optimization of a noise-cancelling wide-band CMOS LNA

    This paper discusses noise figure optimization techniques for a noise- cancelling single-ended-to-differential CMOS low-noise amplifier (LNA). In [1], a low noise figure was obtained through cancellation of the drain noise of the common-gate transistor. Contour plots demonstrate that drain noise cancellation does not guarantee an optimal noise figure. The optimal noise figure is achieved by minimizing the un-cancelled noise contributions as well, and utilizing LC resonance to maintain common-gate transistor drain noise cancellation. An LNA with a 0.8-1.8 GHz bandwidth is designed with this optimization. Simulations show a noise figure between 2.8dB and 1.3dB, with S21≈ 13dB over the bandwidth.

  • On the application of variable-step adaptive noise cancelling for improving the robustness of speech recognition

    As speech recognition and spoken language technologies are being transferred to real applications, the need for greater robustness against adverse noise is becoming increasingly apparent. This paper researches a robust speech recognition method based on adaptive noise cancelling (ANC). It obtained the enhanced speech signal by applying a variable-step adaptive noise cancelling algorithm to reduce noise as pre-treatment of speech recognition under strong noise circumstance. Mel-frequency cepstral coefficients (MFCC) were then computed as recognition features. Compared with conventional spectral subtraction (SS), standard MFCC recognizer and adaptive noise cancelling algorithm in literature, experimental results indicate that this method performs better when signal-to-noise ratio (SNR) ranges from -10 to 15 dB. In addition, the presented method denotes good noise robustness when SNR decreases.

  • A Digital Phase Noise Cancelling Scheme for Ring Oscillator-based Fractional-N ADPLL

    This paper presents a digital phase noise cancelling scheme for ring oscillator (RO)-based fractional-N ADPLL, which can suppress both in-band and out-of-band phase noise of RO. The scheme adopts a high-resolution time-to- digital convertor (TDC) to sample the rising edge timing errors between RO output and the reference signal (REF) and a matched digital-to-time convertor (DTC) to compensate these timing errors to align RO output with each rising edge of REF, eliminating the phase noise of RO output. To get accurate phase noise cancelling, it is essential to realize high resolution and good match between TDC and DTC. These two modules are implemented in 40 nm CMOS with 2 ps resolution and 8.34% mismatch. System-level simulation results show that, the in-band phase noise at 1 MHz offset can be cancelled by the level of 20 dB and the out-of-band phase noise at 10 MHz offset can be cancelled by 10 dB, with the 200 MHz reference signal.

  • A 1.3 V noise-cancelling low noise amplifier for ultra wideband applications

    An ultra wideband (UWB) noise-cancelling low-noise amplifier (NCLNA) is proposed in this paper. A common-gate input stage with an input matching network is implemented to make input resistance matching to 50-ohm. The power consumption of the presented NCLNA can be lower by using current-reuse architecture. A noise cancelling technique is adopted to decrease the noise generated by the first common-gate stage. The designed NCLNA is implemented in 180 nm CMOS technology. The simulated results show that the noise figure is among 2.65-3.45 dB within the full bandwidth of 3.1-10.6 GHz. The maximum gain is 15.33 dB in the desired UWB band. Both the input and output reflection coefficients are below -10 dB. The linearity IIP3 is -5.5 dBm at 6 GHz. The core circuit consumption is 9.13mW under a 1.3 V supply voltage.

  • A 6.3–6.8GHz LNA with noise cancelling and adjacent channel rejection for wideband mobile communication

    This paper discusses a 6.3-6.8GHz single-ended-to-differential LNA with noise- cancelling and adjacent channel rejection for wideband mobile communication. Different from traditional noise-cancelling LNA, this circuit includes local feedback, current reuse and considering bond-wire effect. Besides, this design utilizes a couple of differential-to-single buffers to reduce the mismatch of the differential signal output from single-ended-to-differential LNA. Bond- wire inductance and ESD is inevitable for the chip, but they usually bring about some negative effects. However bond-wire inductance can also be used for impedance matching and acting as current-source. To boost the LNA performance, the layout should be optimized to minimize the device and interconnection parasitic effects. Fabricated in a TSMC 0.13μm RF CMOS process, the LNA achieves a gain of 25dB and a NF of 2.0 dB over the band. It consumes 7.8mA from 1.2V supply and occupies an area of 0.5mm2.

  • A CMOS active balun-LNA with imbalance correction and noise cancelling

    This paper presents an active balun topology with differential imbalance correction and noise cancelling schemes. The imbalance correction scheme can effectively ameliorate both the magnitude and phase errors induced by circuit asymmetry, parasitic and layout mismatch. Noise cancelling exists in each individual stage, which leads to good noise performance. With sufficient gain and low noise figure, this balun can also work as a low noise amplifier (LNA) in RF front end. Implemented in 65nm CMOS process, the balun-LNA exhibits maximum power gain of 16dB, minimum noise figure of 3.8dB and input matching better than -20dB. The measured magnitude and phase errors are less than 0.6dB and 7o, respectively.

  • A Wide-band noise-cancelling CMOS LNA based on Current Conveyors

    In this paper, a Wide-band CMOS low-noise amplifier (LNA) based on Current Conveyors (CC) is presented, in which the thermal noise of the input MOSFET is cancelled by exploiting a noise-cancelling technique. This new LNA offers the following notable advantages over existing topologies: wideband performance, with a stable frequency response from 0 to 6.2GHz and wideband input matched impedance with a total absence of passive elements; a low Noise Figure (NF) and high linearity. Comparisons with other topologies prove the effectiveness of the new implementation.

  • An ultra-wideband common gate LNA with g<inf>m</inf>-boosted and noise cancelling techniques

    In this paper, an ultra-wideband (UWB) common gate low-noise amplifier (LNA) with gm-boosted and noise-cancelling techniques is presented In this scheme we utilize gm-boosted stage for cancelling the noise of matching device. The bandwidth extension and flat gain are achieved by using of series and shunt peaking techniques. Simulated in .13 um Cmos technology, the proposed LNA achieved 2.38-3.4dB NF and S11 less than -11dB in the 3.1-10.6 GHz band Maximum power gain(S21) is 11dB and -3dB bandwidth is 1.25-11.33 GHz. The power consumption of LNA is 5.8mW.

  • A wideband noise cancelling balun-LNA

    In this paper a wideband noise cancelling low noise amplifier is presented. In order to achieve input impedance matching of 50 Ω, in a wide frequency band, the input stage is realized by a common-source stage with resistive feedback. To cancel out the noise of the matching input structure, the CMOS-inverter architecture is used, which achieves the high gain with low current consumption. Simulation results with Spectre RF, using TSMC 180nm show that the proposed amplifier delivers the high gain value of 26.6-31.8 dB all over the 0.1-5 GHz band of interest. Also the S11 of the LNA stays below -9.7 dB all-entire the band of interest. The proposed balun-LNA has the minimum NF value of 2.3 dB and it consumes 16.2 mW from 1.8 V voltage supply.

  • A 1.2-V Highly Linear Balanced Noise-Cancelling LNA in 0.13-<formula formulatype="inline"><tex>$\mu{\hbox{m}}$</tex></formula> CMOS

    In this paper, a current-to-voltage combiner is proposed to realize a highly linear, balanced noise-cancelling low-noise amplifier (LNA) capable of low- voltage operation. The current-to-voltage combiner, implemented in the load of the amplifier, converts the output currents of the parallel common-gate (CG) and common-source (CS) stages of the LNA to voltages, equalizes the amplitudes of the voltages, and combines the voltages to a single output voltage. Since only a CS stage and passive components are employed to cancel the noise and distortion due to the CG input impedance matching circuit, high linearity is achieved in spite of the low supply voltage of 1.2 V. The LNA achieves a noise figure (NF) of 3.0 dB at 2.1 GHz with an input-referred third-order intercept point (IIP3) of +10.5 dBm while consuming 10.5 mA from a 1.2-V supply. The amplifier is fabricated in 0.13-mum CMOS process.



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