Search

Your search keyword '"Ellguth, Georg"' showing total 39 results
Start Over Author "Ellguth, Georg"
39 results on '"Ellguth, Georg"'

1. 68-Channel Highly-Integrated Neural Signal Processing PSoC with On-Chip Feature Extraction, Compression, and Hardware Accelerators for Neuroprosthetics in 22nm FDSOI

Author

Guo, Liyuan, Weiße, Annika, Zeinolabedin, Seyed Mohammad Ali, Schüffny, Franz Marcus, Stolba, Marco, Ma, Qier, Wang, Zhuo, Scholze, Stefan, Dixius, Andreas, Berthel, Marc, Partzsch, Johannes, Walter, Dennis, Ellguth, Georg, Höppner, Sebastian, George, Richard, and Mayr, Christian

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

Multi-channel electrophysiology systems for recording of neuronal activity face significant data throughput limitations, hampering real-time, data-informed experiments. These limitations impact both experimental neurobiology research and next-generation neuroprosthetics. We present a novel solution that leverages the high integration density of 22nm FDSOI CMOS technology to address these challenges. The proposed highly integrated programmable System-on-Chip comprises 68-channel 0.41 \textmu W/Ch recording frontends, spike detectors, 16-channel 0.87-4.39 \textmu W/Ch action potential and 8-channel 0.32 \textmu W/Ch local field potential codecs, as well as a MAC-assisted power-efficient processor operating at 25 MHz (5.19 \textmu W/MHz). The system supports on-chip training processes for compression, training and inference for neural spike sorting. The spike sorting achieves an average accuracy of 91.48% or 94.12% depending on the utilized features. The proposed PSoC is optimized for reduced area (9 mm2) and power. On-chip processing and compression capabilities free up the data bottlenecks in data transmission (up to 91% space saving ratio), and moreover enable a fully autonomous yet flexible processor-driven operation. Combined, these design considerations overcome data-bottlenecks by allowing on-chip feature extraction and subsequent compression., Comment: 26 pages, 14 figures, 1 table, Journal

Published
2024

2. Hardware Implementation of an OPC UA Server for Industrial Field Devices

Author

Bauer, Heiner, Höppner, Sebastian, Iatrou, Chris, Charania, Zohra, Hartmann, Stephan, Rehman, Saif-Ur, Dixius, Andreas, Ellguth, Georg, Walter, Dennis, Uhlig, Johannes, Neumärker, Felix, Berthel, Marc, Stolba, Marco, Kelber, Florian, Urbas, Leon, and Mayr, Christian

Subjects
Computer Science - Hardware Architecture
Abstract

Industrial plants suffer from a high degree of complexity and incompatibility in their communication infrastructure, caused by a wild mix of proprietary technologies. This prevents transformation towards Industry 4.0 and the Industrial Internet of Things. Open Platform Communications Unified Architecture (OPC UA) is a standardized protocol that addresses these problems with uniform and semantic communication across all levels of the hierarchy. However, its adoption in embedded field devices, such as sensors and actors, is still lacking due to prohibitive memory and power requirements of software implementations. We have developed a dedicated hardware engine that offloads processing of the OPC UA protocol and enables realization of compact and low-power field devices with OPC UA support. As part of a proof-of-concept embedded system we have implemented this engine in a 22 nm FDSOI technology. We measured performance, power consumption, and memory footprint of our test chip and compared it with a software implementation based on open62541 and a Raspberry Pi 2B. Our OPC UA hardware engine is 50 times more energy efficient and only requires 36 KiB of memory. The complete chip consumes only 24 mW under full load, making it suitable for low-power embedded applications., Comment: 5 pages, 6 figures, 2 tables

Published
2021
Full Text
View/download PDF

3. The SpiNNaker 2 Processing Element Architecture for Hybrid Digital Neuromorphic Computing

Author

Höppner, Sebastian, Yan, Yexin, Dixius, Andreas, Scholze, Stefan, Partzsch, Johannes, Stolba, Marco, Kelber, Florian, Vogginger, Bernhard, Neumärker, Felix, Ellguth, Georg, Hartmann, Stephan, Schiefer, Stefan, Hocker, Thomas, Walter, Dennis, Liu, Genting, Garside, Jim, Furber, Steve, and Mayr, Christian

Subjects
Computer Science - Hardware Architecture
Abstract

This paper introduces the processing element architecture of the second generation SpiNNaker chip, implemented in 22nm FDSOI. On circuit level, the chip features adaptive body biasing for near-threshold operation, and dynamic voltage-and-frequency scaling driven by spiking activity. On system level, processing is centered around an ARM M4 core, similar to the processor-centric architecture of the first generation SpiNNaker. To speed operation of subtasks, we have added accelerators for numerical operations of both spiking (SNN) and rate based (deep) neural networks (DNN). PEs communicate via a dedicated, custom-designed network-on-chip. We present three benchmarks showing operation of the whole processor element on SNN, DNN and hybrid SNN/DNN networks.

Published
2021

4. Dynamic Power Management for Neuromorphic Many-Core Systems

Author

Hoeppner, Sebastian, Vogginger, Bernhard, Yan, Yexin, Dixius, Andreas, Scholze, Stefan, Partzsch, Johannes, Neumaerker, Felix, Hartmann, Stephan, Schiefer, Stefan, Ellguth, Georg, Cederstroem, Love, Plana, Luis, Garside, Jim, Furber, Steve, and Mayr, Christian

Subjects
Computer Science - Neural and Evolutionary Computing
Abstract

This work presents a dynamic power management architecture for neuromorphic many core systems such as SpiNNaker. A fast dynamic voltage and frequency scaling (DVFS) technique is presented which allows the processing elements (PE) to change their supply voltage and clock frequency individually and autonomously within less than 100 ns. This is employed by the neuromorphic simulation software flow, which defines the performance level (PL) of the PE based on the actual workload within each simulation cycle. A test chip in 28 nm SLP CMOS technology has been implemented. It includes 4 PEs which can be scaled from 0.7 V to 1.0 V with frequencies from 125 MHz to 500 MHz at three distinct PLs. By measurement of three neuromorphic benchmarks it is shown that the total PE power consumption can be reduced by 75%, with 80% baseline power reduction and a 50% reduction of energy per neuron and synapse computation, all while maintaining temporary peak system performance to achieve biological real-time operation of the system. A numerical model of this power management model is derived which allows DVFS architecture exploration for neuromorphics. The proposed technique is to be used for the second generation SpiNNaker neuromorphic many core system.

Published
2019

5. 68-channel neural signal processing system-on-chip with integrated feature extraction, compression, and hardware accelerators for neuroprosthetics in 22 nm FDSOI.

Author

Guo, Liyuan, Weiße, Annika, Zeinolabedin, Seyed Mohammad Ali, Schüffny, Franz Marcus, Stolba, Marco, Ma, Qier, Wang, Zhuo, Scholze, Stefan, Dixius, Andreas, Berthel, Marc, Partzsch, Johannes, Walter, Dennis, Ellguth, Georg, Höppner, Sebastian, George, Richard, and Mayr, Christian

Subjects
MEDICAL electronics, BIOMEDICAL signal processing, DIGITAL integrated circuits, SIGNAL processing, DIGITAL signal processing
Abstract

Introduction: Multi-channel electrophysiology systems for recording of neuronal activity face significant data throughput limitations, hampering real-time, data-informed experiments. These limitations impact both experimental neurobiology research and next-generation neuroprosthetics. Methods: We present a novel solution that leverages the high integration density of 22nm fully-depleted silicon-on-insulator technology to address these challenges. The proposed highly integrated programmable System-on-Chip (SoC) comprises 68-channel 0.41 μW/Ch recording frontends, spike detectors, 16-channel 0.87–4.39 μW/Ch action potentials and 8-channel 0.32 μW/Ch local field potential codecs, as well as a multiply-accumulate-assisted power-efficient processor operating at 25 MHz (5.19 μW/MHz). The system supports on-chip training processes for compression, training, and inference for neural spike sorting. The spike sorting achieves an average accuracy of 91.48 or 94.12% depending on the utilized features. The proposed programmable SoC is optimized for reduced area (9 mm2) and power. On-chip processing and compression capabilities free up the data bottlenecks in data transmission (up to 91% space saving ratio), and moreover enable a fully autonomous yet flexible processor-driven operation. Discussion: Combined, these design considerations overcome data-bottlenecks by allowing on-chip feature extraction and subsequent compression. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

6. Switched-Capacitor Realization of Presynaptic Short-Term-Plasticity and Stop-Learning Synapses in 28 nm CMOS

Author

Noack, Marko, Partzsch, Johannes, Mayr, Christian, Hänzsche, Stefan, Scholze, Stefan, Höppner, Sebastian, Ellguth, Georg, and Schüffny, Rene

Subjects
Computer Science - Emerging Technologies
Abstract

Synaptic dynamics, such as long- and short-term plasticity, play an important role in the complexity and biological realism achievable when running neural networks on a neuromorphic IC. For example, they endow the IC with an ability to adapt and learn from its environment. In order to achieve the mil- lisecond to second time constants required for these synaptic dynamics, analog subthreshold circuits are usually employed. However, due to process variation and leakage problems, it is almost impossible to port these types of circuits to modern sub-100nm technologies. In contrast, we present a neuromor- phic system in a 28 nm CMOS process that employs switched capacitor (SC) circuits to implement 128 short term plasticity presynapses as well as 8192 stop-learning synapses. The neuromorphic system consumes an area of 0.36 mm2 and runs at a power consumption of 1.9 mW. The circuit makes use of a technique for minimizing leakage effects allowing for real-time operation with time constants up to sev- eral seconds. Since we rely on SC techniques for all calculations, the system is composed of only generic mixed-signal building blocks. These generic building blocks make the system easy to port between technologies and the large digital circuit part inherent in an SC system benefits fully from technology scaling.

Published
2014

7. A Biological-Realtime Neuromorphic System in 28 nm CMOS using Low-Leakage Switched Capacitor Circuits

Author

Mayr, Christian, Partzsch, Johannes, Noack, Marko, Hänzsche, Stefan, Scholze, Stefan, Höppner, Sebastian, Ellguth, Georg, and Schüffny, Rene

Subjects
Computer Science - Emerging Technologies
Abstract

A switched-capacitor (SC) neuromorphic system for closed-loop neural coupling in 28 nm CMOS is presented, occupying 600 um by 600 um. It offers 128 input channels (i.e. presynaptic terminals), 8192 synapses and 64 output channels (i.e. neurons). Biologically realistic neuron and synapse dynam- ics are achieved via a faithful translation of the behavioural equations to SC circuits. As leakage currents significantly affect circuit behaviour at this technology node, dedicated compensation techniques are employed to achieve biological-realtime operation, with faithful reproduction of time constants of several 100 ms at room temperature. Power draw of the overall system is 1.9 mW.

Published
2014

9. A 16-Channel Fully Configurable Neural SoC With 1.52 $\mu$W/Ch Signal Acquisition, 2.79 $\mu$W/Ch Real-Time Spike Classifier, and 1.79 TOPS/W Deep Neural Network Accelerator in 22 nm FDSOI

Author

Zeinolabedin, Seyed Mohammad Ali, primary, Schuffny, Franz Marcus, additional, George, Richard, additional, Kelber, Florian, additional, Bauer, Heiner, additional, Scholze, Stefan, additional, Hanzsche, Stefan, additional, Stolba, Marco, additional, Dixius, Andreas, additional, Ellguth, Georg, additional, Walter, Dennis, additional, Hoppner, Sebastian, additional, and Mayr, Christian, additional

Published
2022
Full Text
View/download PDF

10. Hardware Implementation of an OPC UA Server for Industrial Field Devices

Author

Bauer, Heiner, primary, Hoppner, Sebastian, additional, Iatrou, Chris, additional, Charania, Zohra, additional, Hartmann, Stephan, additional, Rehman, Saif Ur, additional, Dixius, Andreas, additional, Ellguth, Georg, additional, Walter, Dennis, additional, Uhlig, Johannes, additional, Neumarker, Felix, additional, Berthel, Marc, additional, Stolba, Marco, additional, Kelber, Florian, additional, Urbas, Leon, additional, and Mayr, Christian, additional

Published
2021
Full Text
View/download PDF

11. A 16-Channel Fully Configurable Neural SoC With 1.52 $\mu$ W/Ch Signal Acquisition, 2.79 $\mu$ W/Ch Real-Time Spike Classifier, and 1.79 TOPS/W Deep Neural Network Accelerator in 22 nm FDSOI.

Author

Zeinolabedin, Seyed Mohammad Ali, Schuffny, Franz Marcus, George, Richard, Kelber, Florian, Bauer, Heiner, Scholze, Stefan, Hanzsche, Stefan, Stolba, Marco, Dixius, Andreas, Ellguth, Georg, Walter, Dennis, Hoppner, Sebastian, and Mayr, Christian

Abstract

With the advent of high-density micro-electrodes arrays, developing neural probes satisfying the real-time and stringent power-efficiency requirements becomes more challenging. A smart neural probe is an essential device in future neuroscientific research and medical applications. To realize such devices, we present a 22 nm FDSOI SoC with complex on-chip real-time data processing and training for neural signal analysis. It consists of a digitally-assisted 16-channel analog front-end with 1.52 $\mu$ W/Ch, dedicated bio-processing accelerators for spike detection and classification with 2.79 $\mu$ W/Ch, and a 125 MHz RISC-V CPU, utilizing adaptive body biasing at 0.5 V with a supporting 1.79 TOPS/W MAC array. The proposed SoC shows a proof-of-concept of how to realize a high-level integration of various on-chip accelerators to satisfy the neural probe requirements for modern applications. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

13. Dynamic Power Management for Neuromorphic Many-Core Systems

Author

Hoppner, Sebastian, primary, Vogginger, Bernhard, additional, Yan, Yexin, additional, Dixius, Andreas, additional, Scholze, Stefan, additional, Partzsch, Johannes, additional, Neumarker, Felix, additional, Hartmann, Stephan, additional, Schiefer, Stefan, additional, Ellguth, Georg, additional, Cederstroem, Love, additional, Plana, Luis A., additional, Garside, Jim, additional, Furber, Steve, additional, and Mayr, Christian, additional

Published
2019
Full Text
View/download PDF

14. A Heterogeneous SDR MPSoC in 28 nm CMOS for Low-Latency Wireless Applications

Author

Haas, Sebastian, primary, Seifert, Tobias, additional, Nöthen, Benedikt, additional, Scholze, Stefan, additional, Höppner, Sebastian, additional, Dixius, Andreas, additional, Adeva, Esther Pérez, additional, Augustin, Thomas, additional, Pauls, Friedrich, additional, Moriam, Sadia, additional, Hasler, Mattis, additional, Fischer, Erik, additional, Chen, Yong, additional, Matúš, Emil, additional, Ellguth, Georg, additional, Hartmann, Stephan, additional, Schiefer, Stefan, additional, Cederström, Love, additional, Walter, Dennis, additional, Henker, Stephan, additional, Hänzsche, Stefan, additional, Uhlig, Johannes, additional, Eisenreich, Holger, additional, Weithoffer, Stefan, additional, Wehn, Norbert, additional, Schüffny, René, additional, Mayr, Christian, additional, and Fettweis, Gerhard, additional

Published
2017
Full Text
View/download PDF

15. Dynamic voltage and frequency scaling for neuromorphic many-core systems

Author

Hoppner, Sebastian, primary, Yan, Yexin, additional, Vogginger, Bernhard, additional, Dixius, Andreas, additional, Partzsch, Johannes, additional, Neumarker, Felix, additional, Hartmann, Stephan, additional, Schiefer, Stefan, additional, Scholze, Stefan, additional, Ellguth, Georg, additional, Cederstroem, Love, additional, Eberlein, Matthias, additional, Mayr, Christian, additional, Temple, Steve, additional, Plana, Luis, additional, Garside, Jim, additional, Davison, Simon, additional, Lester, David R., additional, and Furber, Steve, additional

Published
2017
Full Text
View/download PDF

16. Live demonstration: Dynamic voltage and frequency scaling for neuromorphic many-core systems

Author

Hoppner, Sebastian, primary, Yan, Yexin, additional, Vogginger, Bernhard, additional, Dixius, Andreas, additional, Partzsch, Johannes, additional, Joshi, Prateek, additional, Neumarker, Felix, additional, Hartmann, Stephan, additional, Schiefer, Stefan, additional, Scholze, Stefan, additional, Ellguth, Georg, additional, Cederstroem, Love, additional, Eberlein, Matthias, additional, Mayr, Christian, additional, Temple, Steve, additional, Plana, Luis, additional, Garside, Jim, additional, Davison, Simon, additional, Lester, David R., additional, and Furber, Steve, additional

Published
2017
Full Text
View/download PDF

17. A database accelerator for energy-efficient query processing and optimization

Author

Lehner, Wolfgang, Haas, Sebastian, Arnold, Oliver, Scholze, Stefan, Höppner, Sebastian, Ellguth, Georg, Dixius, Andreas, Ungethüm, Annett, Mier, Eric, Nöthen, Benedikt, Matúš, Emil, Schiefer, Stefan, Cederstroem, Love, Pilz, Fabian, Mayr, Christian, Schüffny, Renè, Fettweis, Gerhard P., Lehner, Wolfgang, Haas, Sebastian, Arnold, Oliver, Scholze, Stefan, Höppner, Sebastian, Ellguth, Georg, Dixius, Andreas, Ungethüm, Annett, Mier, Eric, Nöthen, Benedikt, Matúš, Emil, Schiefer, Stefan, Cederstroem, Love, Pilz, Fabian, Mayr, Christian, Schüffny, Renè, and Fettweis, Gerhard P.

Abstract

Data processing on a continuously growing amount of information and the increasing power restrictions have become an ubiquitous challenge in our world today. Besides parallel computing, a promising approach to improve the energy efficiency of current systems is to integrate specialized hardware. This paper presents a Tensilica RISC processor extended with an instruction set to accelerate basic database operators frequently used in modern database systems. The core was taped out in a 28 nm SLP CMOS technology and allows energy-efficient query processing as well as query optimization by applying selectivity estimation techniques. Our chip measurements show an 1000x energy improvement on selected database operators compared to state-of-the-art systems.

Published
2016

18. A database accelerator for energy-efficient query processing and optimization

Author

Haas, Sebastian, primary, Arnold, Oliver, additional, Scholze, Stefan, additional, Hoppner, Sebastian, additional, Ellguth, Georg, additional, Dixius, Andreas, additional, Ungethum, Annett, additional, Mier, Eric, additional, Nothen, Benedikt, additional, Matus, Emil, additional, Schiefer, Stefan, additional, Cederstroem, Love, additional, Pilz, Fabian, additional, Mayr, Christian, additional, Schuffny, Rene, additional, Lehner, Wolfgang, additional, and Fettweis, Gerhard P., additional

Published
2016
Full Text
View/download PDF

19. An MPSoC for energy-efficient database query processing

Author

Haas, Sebastian, primary, Arnold, Oliver, additional, Nöthen, Benedikt, additional, Scholze, Stefan, additional, Ellguth, Georg, additional, Dixius, Andreas, additional, Höppner, Sebastian, additional, Schiefer, Stefan, additional, Hartmann, Stephan, additional, Henker, Stephan, additional, Hocker, Thomas, additional, Schreiter, Jörg, additional, Eisenreich, Holger, additional, Schlüßler, Jens-Uwe, additional, Walter, Dennis, additional, Seifert, Tobias, additional, Pauls, Friedrich, additional, Hasler, Mattis, additional, Chen, Yong, additional, Hensel, Hermann, additional, Moriam, Sadia, additional, Matúš, Emil, additional, Mayr, Christian, additional, Schüffny, René, additional, and Fettweis, Gerhard P., additional

Published
2016
Full Text
View/download PDF

21. Switched-capacitor realization of presynaptic short-term-plasticity and stop-learning synapses in 28 nm CMOS

Author

Noack, Marko, Partzsch, Johannes, Mayr, Christian G, Hänzsche, Stephan, Scholze, Stefan, Höppner, Sebastian, Ellguth, Georg, Schüffny, Rene, Noack, Marko, Partzsch, Johannes, Mayr, Christian G, Hänzsche, Stephan, Scholze, Stefan, Höppner, Sebastian, Ellguth, Georg, and Schüffny, Rene

Abstract

Synaptic dynamics, such as long- and short-term plasticity, play an important role in the complexity and biological realism achievable when running neural networks on a neuromorphic IC. For example, they endow the IC with an ability to adapt and learn from its environment. In order to achieve the millisecond to second time constants required for these synaptic dynamics, analog subthreshold circuits are usually employed. However, due to process variation and leakage problems, it is almost impossible to port these types of circuits to modern sub-100nm technologies. In contrast, we present a neuromorphic system in a 28 nm CMOS process that employs switched capacitor (SC) circuits to implement 128 short term plasticity presynapses as well as 8192 stop-learning synapses. The neuromorphic system consumes an area of 0.36 mm(2) and runs at a power consumption of 1.9 mW. The circuit makes use of a technique for minimizing leakage effects allowing for real-time operation with time constants up to several seconds. Since we rely on SC techniques for all calculations, the system is composed of only generic mixed-signal building blocks. These generic building blocks make the system easy to port between technologies and the large digital circuit part inherent in an SC system benefits fully from technology scaling.

Published
2015

22. A Heterogeneous SDR MPSoC in 28nmCMOS for Low-Latency Wireless Applications.

Author

Haas, Sebastian, Seifert, Tobias, Nöthen, Benedikt, Scholze, Stefan, Höppner, Sebastian, Dixius, Andreas, Adeva, Esther Pérez, Augustin, Thomas, Pauls, Friedrich, Moriam, Sadia, Hasler, Mattis, Fischer, Erik, Yong Chen, Matúš, Emil, Ellguth, Georg, Hartmann, Stephan, Schiefer, Stefan, Cederström, Love, Walter, Dennis, and Henker, Stephan

Subjects
MIMO systems, WIRELESS communications, DATA analytics, DATA mining, DATA flow computing
Abstract

Current and future applications impose high demands on softwarede fined radio (SDR) platforms in terms of latency, reliability, and flexibility. This paper presents a heterogeneous SDR MPSoC with a hexagonal network-on-chip to address these issues. It features four data processing modules and a baseband processing engine for iterative multiple-input multiple-output (MIMO) receiving. Integrated memory controllers enable dynamic data flow mapping and application isolation. In a 4 x 4 MIMO application scenario, the MPSoC achieves a throughput of 232 Mbit/s with a latency of 20 μs while consuming 414mW. It outperforms state-of-the-art platforms in terms of throughput by a factor of 4. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

25. An MPSoC for Energy-Efficient Database Query Processing.

Author

Haas, Sebastian, Arnold, Oliver, Nöthen, Benedikt, Scholze, Stefan, Ellguth, Georg, Dixius, Andreas, Höppner, Sebastian, Schiefer, Stefan, Hartmann, Stephan, Henker, Stephan, Hocker, Thomas, Schreiter, Jörg, Eisenreich, Holger, Schlüßler, Jens-Uwe, Walter, Dennis, Seifert, Tobias, Pauls, Friedrich, Hasler, Mattis, Yong Chen, and Hensel, Hermann

Subjects
MULTIPROCESSORS, NETWORKS on a chip, SEARCH algorithms, BIT-mapped graphics, INFORMATION storage & retrieval systems
Abstract

This paper presents a heterogeneous database hardware accelerator MPSoC manufactured in 28 nm SLP CMOS. The 18 mm2 chip integrates a runtime task scheduling unit for energy-efficient query processing and hierarchical power management supported by an ultra-fast dynamic voltage and frequency scaling. Four processing elements, connected by a star-mesh network-on-chip, are accelerated by an instruction set extension tailored to fundamental data-intensive applications. We evaluate the MPSoC with typical database benchmarks focusing on scans and bitmap operations. When the processing elements operate on data stored in local memories, the chip consumes 250 mW and shows a 96x energy efficiency improvement compared to state-of- the-art platforms. [ABSTRACT FROM AUTHOR]

Published
2016
Full Text
View/download PDF

28. 10.7 A 105GOPS 36mm2 heterogeneous SDR MPSoC with energy-aware dynamic scheduling and iterative detection-decoding for 4G in 65nm CMOS

Author

Noethen, Benedikt, primary, Arnold, Oliver, additional, Adeva, Esther Perez, additional, Seifert, Tobias, additional, Fischer, Erik, additional, Kunze, Steffen, additional, Matus, Emil, additional, Fettweis, Gerhard, additional, Eisenreich, Holger, additional, Ellguth, Georg, additional, Hartmann, Stephan, additional, Hoppner, Sebastian, additional, Schiefer, Stefan, additional, Schlusler, Jens-Uwe, additional, Scholze, Stefan, additional, Walter, Dennis, additional, and Schuffny, Rene, additional

Published
2014
Full Text
View/download PDF

34. A 335Mb/s 3.9mm2 65nm CMOS flexible MIMO detection-decoding engine achieving 4G wireless data rates

Author

Winter, Markus, primary, Kunze, Steffen, additional, Adeva, Esther Perez, additional, Mennenga, Bjorn, additional, Matus, Emil, additional, Fettweis, Gerhard, additional, Eisenreich, Holger, additional, Ellguth, Georg, additional, Hoppner, Sebastian, additional, Scholze, Stefan, additional, Schuffny, Rene, additional, and Kobori, Tomoyoshi, additional

Published
2012
Full Text
View/download PDF

39. A 16-Channel Fully Configurable Neural SoC With 1.52 μW/Ch Signal Acquisition, 2.79 μW/Ch Real-Time Spike Classifier, and 1.79 TOPS/W Deep Neural Network Accelerator in 22 nm FDSOI.

Author

Zeinolabedin SMA, Schuffny FM, George R, Kelber F, Bauer H, Scholze S, Hanzsche S, Stolba M, Dixius A, Ellguth G, Walter D, Hoppner S, and Mayr C

Subjects
Cyclic N-Oxides, Electrodes, Neural Networks, Computer, Signal Processing, Computer-Assisted
Abstract

With the advent of high-density micro-electrodes arrays, developing neural probes satisfying the real-time and stringent power-efficiency requirements becomes more challenging. A smart neural probe is an essential device in future neuroscientific research and medical applications. To realize such devices, we present a 22 nm FDSOI SoC with complex on-chip real-time data processing and training for neural signal analysis. It consists of a digitally-assisted 16-channel analog front-end with 1.52 μW/Ch, dedicated bio-processing accelerators for spike detection and classification with 2.79 μW/Ch, and a 125 MHz RISC-V CPU, utilizing adaptive body biasing at 0.5 V with a supporting 1.79 TOPS/W MAC array. The proposed SoC shows a proof-of-concept of how to realize a high-level integration of various on-chip accelerators to satisfy the neural probe requirements for modern applications.

Published
2022
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results