Wireless multichannel biopotential recording using an integrated FM telemetry circuit

Mohseni,; Najafi, Bijan

doi:10.1109/iembs.2004.1404139

Cited by 54 publications

(47 citation statements)

References 6 publications

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“…The high-pass corner frequency of this stage is (1) where is the resistance of the subthreshold MOS resistors. The resistance of a subthreshold MOS resistor is governed by (2) where , , , , and are the device width, length, carrier mobility, subthreshold-slope factor, and gate capacitance, respectively [16]. In addition, is the thermal voltage, is the gate-source voltage (controllable by the 12-bit mote DAC), is the drain-source voltage, and is the carrier Fermi energy [17].…”

Section: A Hardwarementioning

confidence: 99%

Embedded Neural Recording With TinyOS-Based Wireless-Enabled Processor Modules

Farshchi

Pesterev

Nuyujukian

et al. 2010

IEEE Trans. Neural Syst. Rehabil. Eng.

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Abstract-To create a wireless neural recording system that can benefit from the continuous advancements being made in embedded microcontroller and communications technologies, an embedded-system-based architecture for wireless neural recording has been designed, fabricated, and tested. The system consists of commercial-off-the-shelf wireless-enabled processor modules (motes) for communicating the neural signals, and a back-end database server and client application for archiving and browsing the neural signals. A neural-signal-acquisition application has been developed to enable the mote to either acquire neural signals at a rate of 4000 12-bit samples per second, or detect and transmit spike heights and widths sampled at a rate of 16670 12-bit samples per second on a single channel. The motes acquire neural signals via a custom low-noise neural-signal amplifier with adjustable gain and high-pass corner frequency that has been designed, and fabricated in a 1.5-m CMOS process. In addition to browsing acquired neural data, the client application enables the user to remotely toggle modes of operation (real-time or spike-only), as well as amplifier gain and high-pass corner frequency.Index Terms-Biomedical electronics, embedded sensor, low-power circuit design, neural amplifier, unit detection.

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Section: A Hardwarementioning

confidence: 99%

Embedded Neural Recording With TinyOS-Based Wireless-Enabled Processor Modules

Farshchi

Pesterev

Nuyujukian

et al. 2010

IEEE Trans. Neural Syst. Rehabil. Eng.

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“…Matching between the receiver antenna and front-end RF LNA results in transferred noise power of (12) where is the receiver RF front-end bandwidth. At room temperature, (12) in dBm becomes (13) Every stage in Fig. 2 has a thermal noise characterized by its noise factor, , and noise figure .…”

Section: B External Receiver Errorsmentioning

confidence: 99%

“…The advantage of this method is its simplicity and low power consumption. However, analog samples are susceptible to noise, and the transitions from one channel to another in short sampling periods can result in significant crosstalk among adjacent channels on the receiver side [13], [14]. To get a sense of how much information needs to be transferred across the wireless link, we should note that the neural signal spectrum spans from 0.1 Hz to 10 kHz.…”

mentioning

confidence: 99%

Using Pulse Width Modulation for Wireless Transmission of Neural Signals in a Multichannel Neural Recording System

Yin

Ghovanloo

2007

2007 IEEE International Symposium on Circuits and Systems (ISCAS)

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“…FiniteState-Machine (FSM)-based systems [18], [19], [20] to more generic and software-based (µP /µC-based) ones [21], [22], [23]. This trend has been well-studied [16] and is depicted in Fig.1.…”

Section: Processorsmentioning

confidence: 99%

The case for a generic implant processor

Strydis

Gaydadjiev

2008

2008 30th Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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Abstract-A more structured and streamlined design of implants is nowadays possible. In this paper we focus on implant processors located in the heart of implantable systems. We present a real and representative biomedical-application scenario where such a new processor can be employed. Based on a suitably selected processor simulator, various operational aspects of the application are being monitored. Findings on performance, cache behavior, branch prediction, power consumption, energy expenditure and instruction mixes are presented and analyzed. The suitability of such an implant processor and directions for future work are given.

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Wireless multichannel biopotential recording using an integrated FM telemetry circuit

Cited by 54 publications

References 6 publications

Embedded Neural Recording With TinyOS-Based Wireless-Enabled Processor Modules

Embedded Neural Recording With TinyOS-Based Wireless-Enabled Processor Modules

Using Pulse Width Modulation for Wireless Transmission of Neural Signals in a Multichannel Neural Recording System

The case for a generic implant processor

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