64 Channel Neural Recording Amplifier with Tunable Bandwidth in 180 nm CMOS Technology

Gryboś, P.; Kmon, Piotr; Żołądź, M.; Szczygieł, R.; Kachel, Maciej; Lewandowski, M.H.; Blasiak, Tomasz

doi:10.2478/v10178-011-0060-x

Cited by 23 publications

(8 citation statements)

References 21 publications

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“…Due to a large surplus of image throughput, the presented image sensor can be extended to higher resolutions. Based on the presented design, it can be estimated that an image sensor of 128 × 128 resolution, fabricated in 0.18 m CMOS technology [27] would occupy a 6 mm 2 chip area while dissipating only 100 W of supply power.…”

Section: Discussionmentioning

confidence: 99%

Characteristics of an Image Sensor with Early-Vision Processing Fabricated in Standard 0.35 μm Cmos Technology

Jendernalik¹,

Jakusz²,

Blakiewicz³

et al. 2012

Metrology and Measurement Systems

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The article presents measurement results of prototype integrated circuits for acquisition and processing of images in real time. In order to verify a new concept of circuit solutions of analogue image processors, experimental integrated circuits were fabricated. The integrated circuits, designed in a standard 0.35 µm CMOS technology, contain the image sensor and analogue processors that perform low-level convolution-based image processing algorithms. The prototype with a resolution of 32 × 32 pixels allows the acquisition and processing of images at high speed, up to 2000 frames/s. Operation of the prototypes was verified in practice using the developed software and a measurement system based on a FPGA platform.

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Section: Discussionmentioning

confidence: 99%

Characteristics of an Image Sensor with Early-Vision Processing Fabricated in Standard 0.35 μm Cmos Technology

Jendernalik¹,

Jakusz²,

Blakiewicz³

et al. 2012

Metrology and Measurement Systems

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“…To assess how a complex neural network, like brain, codes and processes information, the ECoGs were recorded in absence of and during transcranial electrical stimulation [25]. The data were exported from the Stellate Harmonie system into ASCII text files that were then imported to MATLAB for analysis.…”

Section: Discussionmentioning

confidence: 99%

“…In fact, some important features of the electrophysiological signals determined by timefrequency analysis (e.g., different brain states, from sleep to cognitive processing) are reflected by different oscillations in the ECoG [27]. Spectral analysis was carried out within each band of interest, that is, delta (1-4 Hz), theta (4-7 Hz), alpha (8-13 Hz), beta (14)(15)(16)(17)(18)(19)(20)(21)(22)(23)(24)(25)(26)(27)(28)(29), and gamma (30-100 Hz).…”

Section: Discussionmentioning

confidence: 99%

Biomimetic Sonar for Electrical Activation of the Auditory Pathway

et al. 2017

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Relying on the mechanism of bat's echolocation system, a bioinspired electronic device has been developed to investigate the cortical activity of mammals in response to auditory sensorial stimuli. By means of implanted electrodes, acoustical information about the external environment generated by a biomimetic system and converted in electrical signals was delivered to anatomically selected structures of the auditory pathway. Electrocorticographic recordings showed that cerebral activity response is highly dependent on the information carried out by ultrasounds and is frequency-locked with the signal repetition rate. Frequency analysis reveals that delta and beta rhythm content increases, suggesting that sensorial information is successfully transferred and integrated. In addition, principal component analysis highlights how all the stimuli generate patterns of neural activity which can be clearly classified. The results show that brain response is modulated by echo signal features suggesting that spatial information sent by biomimetic sonar is efficiently interpreted and encoded by the auditory system. Consequently, these results give new perspective in artificial environmental perception, which could be used for developing new techniques useful in treating pathological conditions or influencing our perception of the surroundings. BackgroundUltrasound (US) plays an important role in the environmental perception of many species of mammals (such as rats and bats) for communication and survival; indeed, they use incoming US to gather information about incumbent danger, food availability, and navigational ranging [1]. Although Rodentia and Microchiroptera do not claim a common phylogenetic origin, recent literature reports that there are certain similarities in both mammals regarding anatomical organization [2,3]. Moreover, the cortical area arrangement and cortical frequency processing are similar to other mammals [4][5][6].US frequency range of bats and rats partially overlaps and both eutherian lineages possess similar encoding process of mechanical US waves, although with different aims as spatial navigation and social communication [7,8]. In this study, a method for stimulating rats neural centres by using a bats bioinspired neuroelectronic interface is proposed. The electronic system for US signal processing is based on the natural sonar of Pteronotus parnellii and was previously investigated for modulating brain activity [9,10]. This study demonstrated ultrasound waves, which are properly decoded into bioelectrical signals, travelled along the acoustic pathway, and successfully reached cortical areas, processing sensorial information according to the environment or to cognitive demands. Similarly, exogenous stimulation may alter sensory perception by acting on the neural networks [11].Hereafter, we have investigated how different signal patterns, emulating ultrasound echoes, affected brain activity by means of implanted electrodes connected to an electronic interface. Different patterns of echo signals at 50 ...

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“…This experiment strategy is motivated by the fact that larger amount of data provided by the experiment may result in its deeper comprehension. Therefore, modern technologies are applied to develop systems comprising hundreds of recording sites [5,6]. As a consequence increased data amount that has to be handled, i.e.…”

Section: Introductionmentioning

confidence: 99%

Design of the ultrafast LVDS I/O interface in 40 nm CMOS process

Satława

Drozd

Kmon

2014

2014 Proceedings of the 21st International Conference Mixed Design of Integrated Circuits and Systems (MIXDES)

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This paper presents the design and simulation results of the ultrafast LVDS I/O interface designed in 40 nm CMOS process. The LVDS transmitters and receivers were designed to support a data transfer of a multichannel Integrated Circuit dedicated for readout of hybrid pixel semiconductor detectors used for X-ray imaging applications. The transmitter is based on the current switching bridge architecture while the receiver is built of the inverting comparator with hysteresis. The LVDS I/O interface is supplied from 2.5 V and 0.9 V supply voltage. The transmitter and receiver occupy respectively 0.1 mm 2 and 0.009 mm 2 of chip area. The static/dynamic power consumption of the transmitter and receiver are respectively equal to 17.9/26.4 mW and 7.1/12.1 mW.

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64 Channel Neural Recording Amplifier with Tunable Bandwidth in 180 nm CMOS Technology

Cited by 23 publications

References 21 publications

Characteristics of an Image Sensor with Early-Vision Processing Fabricated in Standard 0.35 μm Cmos Technology

Characteristics of an Image Sensor with Early-Vision Processing Fabricated in Standard 0.35 μm Cmos Technology

Biomimetic Sonar for Electrical Activation of the Auditory Pathway

Design of the ultrafast LVDS I/O interface in 40 nm CMOS process

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