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Johannes Partzsch
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2020 – today
- 2023
- [c34]Liyuan Guo, Matthias Jobst
, Johannes Partzsch
A Low-Power Hardware Accelerator of MFCC Extraction for Keyword Spotting in 22nm FDSOI. AICAS 2023: 1-5 - [c33]Bernhard Vogginger
Performance models and energy-optimal scheduling of DNNs on many-core hardware with dynamic power management. CODAI 2023: 27-31 - [c32]Chen Liu
Deploying Machine Learning Models to Ahead-of-Time Runtime on Edge Using MicroTVM. CODAI 2023: 37-40 - [c31]Liyuan Guo, Seyed Mohammad Ali Zeinolabedin, Franz Marcus Schüffny, Annika Weiße, Stefan Scholze, Richard George, Johannes Partzsch
A 16-channel Real-time Adaptive Neural Signal Compression Engine in 22nm FDSOI. NEWCAS 2023: 1-5 - [i12]Chen Liu, Matthias Jobst
Deploying Machine Learning Models to Ahead-of-Time Runtime on Edge Using MicroTVM. CoRR abs/2304.04842 (2023) - 2022
- [j15]Eric Müller, Sebastian Schmitt, Christian Mauch, Sebastian Billaudelle, Andreas Grübl, Maurice Güttler, Dan Husmann, Joscha Ilmberger, Sebastian Jeltsch, Jakob Kaiser, Johann Klähn, Mitja Kleider, Christoph Koke, José Montes, Paul Müller, Johannes Partzsch
The operating system of the neuromorphic BrainScaleS-1 system. Neurocomputing 501: 790-810 (2022) - [c30]Matthias Jobst
ZEN: A flexible energy-efficient hardware classifier exploiting temporal sparsity in ECG data. AICAS 2022: 214-217 - [c29]Wolfgang Ecker, Peer Adelt, Wolfgang Müller, Reinhold Heckmann, Milos Krstic
The Scale4Edge RISC-V Ecosystem. DATE 2022: 808-813 - [c28]Tim Langer
Hardware-Efficient Ultrasonic Entrance Counting: Comparing Different Machine Learning Approaches. ICPR 2022: 755-761 - 2021
- [j14]Seyed Mohammad Ali Zeinolabedin
Real-time Hardware Implementation of ARM CoreSight Trace Decoder. IEEE Des. Test 38(1): 69-77 (2021) - [j13]Yexin Yan
Comparing Loihi with a SpiNNaker 2 prototype on low-latency keyword spotting and adaptive robotic control. Neuromorph. Comput. Eng. 1(1): 14002 (2021) - [c27]Seyed Mohammad Ali Zeinolabedin
Analyzing ARM CoreSight ETMv4.x Data Trace Stream with a Real-time Hardware Accelerator. DATE 2021: 1606-1609 - [c26]Vasilis N. Thanasoulis, Bernhard Vogginger, Johannes Partzsch
Delay-Based Neural Computation: Pulse Routing Architecture and Benchmark Application in FPGA. ICECS 2021: 1-5 - [i11]Sebastian Höppner, Yexin Yan, Andreas Dixius, Stefan Scholze, Johannes Partzsch, Marco Stolba, Florian Kelber, Bernhard Vogginger, Felix Neumärker, Georg Ellguth, Stephan Hartmann, Stefan Schiefer, Thomas Hocker, Dennis Walter, Gengting Liu, Jim D. Garside, Steve B. Furber, Christian Mayr:
The SpiNNaker 2 Processing Element Architecture for Hybrid Digital Neuromorphic Computing. CoRR abs/2103.08392 (2021) - 2020
- [j12]Johannes Partzsch
Mean Field Approach for Configuring Population Dynamics on a Biohybrid Neuromorphic System. J. Signal Process. Syst. 92(11): 1303-1321 (2020) - [c25]Matthias Jobst
Event-based Neural Network for ECG Classification with Delta Encoding and Early Stopping. EBCCSP 2020: 1-4 - [c24]Florian Kelber, Binyi Wu
Mapping Deep Neural Networks on SpiNNaker2. NICE 2020: 18:1-18:3 - [i10]Eric Müller, Sebastian Schmitt, Christian Mauch
The Operating System of the Neuromorphic BrainScaleS-1 System. CoRR abs/2003.13749 (2020) - [i9]Yexin Yan, Terrence C. Stewart, Xuan Choo, Bernhard Vogginger, Johannes Partzsch, Sebastian Höppner, Florian Kelber, Chris Eliasmith, Steve B. Furber, Christian Mayr:
Low-Power Low-Latency Keyword Spotting and Adaptive Control with a SpiNNaker 2 Prototype and Comparison with Loihi. CoRR abs/2009.08921 (2020)
2010 – 2019
- 2019
- [j11]Yexin Yan
Efficient Reward-Based Structural Plasticity on a SpiNNaker 2 Prototype. IEEE Trans. Biomed. Circuits Syst. 13(3): 579-591 (2019) - [j10]Sebastian Höppner, Bernhard Vogginger
Dynamic Power Management for Neuromorphic Many-Core Systems. IEEE Trans. Circuits Syst. I Regul. Pap. 66-I(8): 2973-2986 (2019) - [i8]Yexin Yan, David Kappel, Felix Neumärker, Johannes Partzsch, Bernhard Vogginger, Sebastian Höppner, Steve B. Furber, Wolfgang Maass, Robert Legenstein, Christian Mayr:
Efficient Reward-Based Structural Plasticity on a SpiNNaker 2 Prototype. CoRR abs/1903.08500 (2019) - [i7]Sebastian Höppner, Bernhard Vogginger, Yexin Yan, Andreas Dixius, Stefan Scholze, Johannes Partzsch, Felix Neumaerker, Stephan Hartmann, Stefan Schiefer, Georg Ellguth, Love Cederstroem, Luis A. Plana, Jim D. Garside, Steve B. Furber, Christian Mayr:
Dynamic Power Management for Neuromorphic Many-Core Systems. CoRR abs/1903.08941 (2019) - [i6]Johannes Partzsch, Christian Mayr, Massimiliano Giulioni, Marko Noack, Stefan Hänzsche, Stefan Scholze, Sebastian Höppner, Paolo Del Giudice, René Schüffny:
Mean Field Approach for Configuring Population Dynamics on a Biohybrid Neuromorphic System. CoRR abs/1904.10389 (2019) - 2017
- [c23]Sebastian Schmitt, Johann Klähn, Guillaume Bellec, Andreas Grübl, Maurice Güttler, Andreas Hartel, Stephan Hartmann, Dan Husmann de Oliveira, Kai Husmann, Sebastian Jeltsch, Vitali Karasenko, Mitja Kleider, Christoph Koke, Alexander Kononov, Christian Mauch
Neuromorphic hardware in the loop: Training a deep spiking network on the BrainScaleS wafer-scale system. IJCNN 2017: 2227-2234 - [c22]Sebastian Höppner, Yexin Yan, Bernhard Vogginger, Andreas Dixius, Johannes Partzsch, Prateek Joshi, Felix Neumärker, Stephan Hartmann, Stefan Schiefer, Stefan Scholze, Georg Ellguth, Love Cederstroem, Matthias Eberlein, Christian Mayr, Steve Temple, Luis A. Plana, Jim D. Garside, Simon Davidson, David R. Lester, Steve B. Furber:
Live demonstration: Dynamic voltage and frequency scaling for neuromorphic many-core systems. ISCAS 2017: 1 - [c21]Sebastian Höppner, Yexin Yan, Bernhard Vogginger, Andreas Dixius, Johannes Partzsch, Felix Neumärker, Stephan Hartmann, Stefan Schiefer, Stefan Scholze, Georg Ellguth, Love Cederstroem, Matthias Eberlein, Christian Mayr, Steve Temple, Luis A. Plana, Jim D. Garside, Simon Davidson, David R. Lester, Steve B. Furber:
Dynamic voltage and frequency scaling for neuromorphic many-core systems. ISCAS 2017: 1-4 - [c20]Johannes Partzsch
A fixed point exponential function accelerator for a neuromorphic many-core system. ISCAS 2017: 1-4 - [c19]Mihai A. Petrovici
Pattern representation and recognition with accelerated analog neuromorphic systems. ISCAS 2017: 1-4 - [c18]Heiner Bauer, Sebastian Höppner, Johannes Partzsch
Exploration of FPGA architectures for tight coupled accelerators in a 22nm FDSOI technology. NORCAS 2017: 1-6 - [i5]Sebastian Schmitt
Neuromorphic Hardware In The Loop: Training a Deep Spiking Network on the BrainScaleS Wafer-Scale System. CoRR abs/1703.01909 (2017) - [i4]Mihai A. Petrovici, Sebastian Schmitt, Johann Klähn, David Stöckel, Anna Schroeder, Guillaume Bellec, Johannes Bill, Oliver Breitwieser, Ilja Bytschok, Andreas Grübl, Maurice Güttler, Andreas Hartel, Stephan Hartmann, Dan Husmann de Oliveira, Kai Husmann, Sebastian Jeltsch, Vitali Karasenko, Mitja Kleider, Christoph Koke, Alexander Kononov, Christian Mauch, Paul Müller, Johannes Partzsch
Pattern representation and recognition with accelerated analog neuromorphic systems. CoRR abs/1703.06043 (2017) - 2016
- [j9]Christian Mayr, Johannes Partzsch
A Biological-Realtime Neuromorphic System in 28 nm CMOS Using Low-Leakage Switched Capacitor Circuits. IEEE Trans. Biomed. Circuits Syst. 10(1): 243-254 (2016) - [j8]Sebastian Höppner
A Calibration Technique for Bang-Bang ADPLLs Using Jitter Distribution Monitoring. IEEE Trans. Very Large Scale Integr. Syst. 24(12): 3548-3552 (2016) - 2014
- [b1]Johannes Partzsch:
Analyse- und Entwurfsmethoden für Verbindungsarchitekturen neuromorpher Systeme. Dresden University of Technology, TUDpress 2014, ISBN 978-3-944331-79-9, pp. 1-145 - [c17]Vasilis N. Thanasoulis, Johannes Partzsch
Configurable pulse routing architecture for accelerated multi-node neuromorphic systems. ICECS 2014: 738-741 - [c16]Vasilis N. Thanasoulis, Bernhard Vogginger, Johannes Partzsch
A pulse communication flow ready for accelerated neuromorphic experiments. ISCAS 2014: 265-268 - [c15]Marko Noack, Markus Krause, Christian Mayr, Johannes Partzsch
VLSI implementation of a conductance-based multi-synapse using switched-capacitor circuits. ISCAS 2014: 850-853 - [i3]Christian Mayr, Michael Schultz, Marko Noack, Stephan Henker, Johannes Partzsch, René Schüffny:
OTA based 200 GΩ resistance on 700 μm2 in 180 nm CMOS for neuromorphic applications. CoRR abs/1409.0171 (2014) - [i2]Christian Mayr, Johannes Partzsch, Marko Noack, Stefan Hänzsche, Stefan Scholze, Sebastian Höppner, Georg Ellguth, René Schüffny:
A Biological-Realtime Neuromorphic System in 28 nm CMOS using Low-Leakage Switched Capacitor Circuits. CoRR abs/1412.3233 (2014) - [i1]Marko Noack, Johannes Partzsch, Christian Mayr, Stefan Hänzsche, Stefan Scholze, Sebastian Höppner, Georg Ellguth, René Schüffny:
Switched-Capacitor Realization of Presynaptic Short-Term-Plasticity and Stop-Learning Synapses in 28 nm CMOS. CoRR abs/1412.3243 (2014) - 2013
- [c14]Johannes Partzsch
Live demonstration: Ethernet communication linking two large-scale neuromorphic systems. ECCTD 2013: 1 - [c13]Alexander D. Rast, Johannes Partzsch, Christian Mayr, Johannes Schemmel
A location-independent direct link neuromorphic interface. IJCNN 2013: 1-8 - [c12]Christian Mayr, Johannes Partzsch, Marko Noack, René Schüffny:
Live demonstration: Multiple-timescale plasticity in a neuromorphic system. ISCAS 2013: 666-670 - 2012
- [j7]Johannes Partzsch
Developing structural constraints on connectivity for biologically embedded neural networks. Biol. Cybern. 106(3): 191-200 (2012) - [j6]Stefan Scholze, Holger Eisenreich, Sebastian Höppner, Georg Ellguth, Stephan Henker, Mario Ander, Stefan Hänzsche, Johannes Partzsch
A 32 GBit/s communication SoC for a waferscale neuromorphic system. Integr. 45(1): 61-75 (2012) - [j5]Stephan Henker, Johannes Partzsch
Accuracy evaluation of numerical methods used in state-of-the-art simulators for spiking neural networks. J. Comput. Neurosci. 32(2): 309-326 (2012) - [c11]Vasilis N. Thanasoulis, Johannes Partzsch
Long-term pulse stimulation and recording in an accelerated neuromorphic system. ICECS 2012: 590-592 - [c10]Vasilis N. Thanasoulis, Johannes Partzsch
Dedicated FPGA communication architecture and design for a large-scale neuromorphic system. ICECS 2012: 877-880 - [c9]Johannes Schemmel
Live demonstration: A scaled-down version of the BrainScaleS wafer-scale neuromorphic system. ISCAS 2012: 702 - [c8]Christian Mayr, Paul Stärke, Johannes Partzsch, René Schüffny, Love Cederstroem, Yao Shuai, Nan Du, Heidemarie Schmidt:
Waveform Driven Plasticity in BiFeO3 Memristive Devices: Model and Implementation. NIPS 2012: 1709-1717 - 2011
- [j4]Daniel Brüderle, Mihai A. Petrovici
A comprehensive workflow for general-purpose neural modeling with highly configurable neuromorphic hardware systems. Biol. Cybern. 104(4-5): 263-296 (2011) - [j3]Johannes Partzsch
Analyzing the Scaling of Connectivity in Neuromorphic Hardware and in Models of Neural Networks. IEEE Trans. Neural Networks 22(6): 919-935 (2011) - [c7]Marko Noack, Christian Mayr, Johannes Partzsch
Synapse dynamics in CMOS derived from a model of neurotransmitter release. ECCTD 2011: 198-201 - [c6]Stefan Schiefer, Stephan Hartmann, Stefan Scholze, Johannes Partzsch
Live demonstration: Packet-based AER with 3Gevent/s cumulative throughput. ISCAS 2011: 1988 - 2010
- [c5]Christian Mayr, Johannes Partzsch, René Schüffny:
A critique of BCM behavior verification for STDP-type plasticity models. ESANN 2010 - [c4]Stephan Hartmann, Stefan Schiefer, Stefan Scholze, Johannes Partzsch
Highly integrated packet-based AER communication infrastructure with 3Gevent/S throughput. ICECS 2010: 950-953 - [c3]Christian Mayr, Marko Noack, Johannes Partzsch
Replicating experimental spike and rate based neural learning in CMOS. ISCAS 2010: 105-108
2000 – 2009
- 2009
- [j2]Christian Mayr, Johannes Partzsch
On the Relation between Bursts and Dynamic Synapse Properties: A Modulation-Based Ansatz. Comput. Intell. Neurosci. 2009: 658474:1-658474:13 (2009) - [j1]Christian Mayr, Johannes Partzsch
Transient responses of activity-dependent synapses to modulated pulse trains. Neurocomputing 73(1-3): 99-105 (2009) - [c2]Johannes Partzsch, René Schüffny:
On the routing complexity of neural network models - Rent's Rule revisited. ESANN 2009 - 2008
- [c1]Johannes Partzsch
BCM and Membrane Potential: Alternative Ways to Timing Dependent Plasticity. ICONIP (1) 2008: 137-144
Coauthor Index
[c34] [c33] [c32] [c31] [i12] [j15] [c30] [c29] [c28] [j14] [j13] [c27] [c26] [i11] [j12] [c25] [c24] [i10] [i9] [j11] [j10] [i8] [i7] [i6] [c23] [c22] [c21] [c20] [c19] [c18] [i5] [i4] [j9] [j8] [c15] [i3] [i2] [i1] [c14] [c13] [c12] [j6] [c11] [c10] [c9] [c8] [j4] [c7] [c6] [c5] [c4] [c3] [j2] [j1] [c1]
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