default search action
Google
Google Scholar
Semantic Scholar
Internet Archive Scholar
CiteSeerX
ORCIDKarlheinz Ochs
Person information
- affiliation: Ruhr University Bochum, Germany
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
2020 – today
- 2024
[j13]Bakr Al Beattie
, Karlheinz Ochs:
A better SPQR-tree decomposition of electrical circuits containing multiports and its application to wave digital emulation. Int. J. Circuit Theory Appl. 52(2): 536-550 (2024)- 2023
- [j12]Bakr Al Beattie, Karlheinz Ochs:
A network-theoretical perspective on oscillator-based Ising machines. Int. J. Circuit Theory Appl. 51(6): 2499-2517 (2023) - [j11]Bakr Al Beattie, Karlheinz Ochs:
Solving a one-dimensional moving boundary problem based on wave digital principles. Multidimens. Syst. Signal Process. 34(4): 703-730 (2023) - [c39]Bharath Kumar Singh Muralidhar, Bakr Al Beattie, Max Uhlmann, Karlheinz Ochs, Gerhard Kahmen, Robert Rieger:
A Bio-Inspired CMOS Circuit for the Excitation and Inhibition of Neuronal Oscillators. APCCAS 2023: 31-35 - [c38]Bakr Al Beattie, Sebastian Jenderny, Jonas Röhrig, Karlheinz Ochs:
Light-Controlled Switching of Gait Patterns in a Central Pattern Generator: Circuit Design and Emulation. ICECS 2023: 1-4 - [c37]Bakr Al Beattie, Bharath Kumar Singh Muralidhar, Max Uhlmann, Gerhard Kahmen, Robert Rieger, Karlheinz Ochs:
Electrical and Wave Digital Modeling of CMOS-Based Ring Oscillators. ICECS 2023: 1-4 - [c36]Max Uhlmann, Tommaso Rizzi, Jianan Wen, Emilio Pérez-Bosch Quesada, Bakr Al Beattie, Karlheinz Ochs, Eduardo Pérez, Philip Ostrovskyy, Corrado Carta, Christian Wenger, Gerhard Kahmen:
LUT-based RRAM Model for Neural Accelerator Circuit Simulation. NANOARCH 2023: 35:1-35:6 - [c35]Sebastian Jenderny, Karlheinz Ochs, Oways Alsoloh:
Wave Digital Emulation of a Light-Modulated Central Pattern Generator. NEWCAS 2023: 1-4 - [c34]Sebastian Jenderny, Karlheinz Ochs, Matthew Gibson, Philipp Hövel:
A Simplified Hindmarsh-Rose Model Based on Power-Flow Analysis. NEWCAS 2023: 1-5 - [c33]Sebastian Jenderny, Karlheinz Ochs, Kamel Naoum Naame:
A Reservoir Computer-Based Modeling of Hunting Dynamics in Predator-Prey Scenarios. NEWCAS 2023: 1-5 - 2022
- [c32]Sebastian Jenderny, Karlheinz Ochs:
Wave Digital Emulation of a Bio-Inspired Circuit for Axon Growth. BioCAS 2022: 260-264 - [c31]Karlheinz Ochs, Bakr Al Beattie:
Towards Wave Digital Modeling of Neural Pathways Using Two-Port Coupling Networks. ISCAS 2022: 809-812 - [c30]Dennis Michaelis, Karlheinz Ochs, Bakr Al Beattie, Sebastian Jenderny:
Towards A Self-Organizing Neuronal Network Based on Guided Axon-Growth. MWSCAS 2022: 1-4 - 2021
- [j10]Karlheinz Ochs, Sebastian Jenderny:
An equivalent electrical circuit for the Hindmarsh-Rose model. Int. J. Circuit Theory Appl. 49(11): 3526-3539 (2021) - [j9]Karlheinz Ochs, Dennis Michaelis, Sebastian Jenderny:
Synthesis of an Equivalent Circuit for Spike-Timing-Dependent Axon Growth: What Fires Together Now Really Wires Together. IEEE Trans. Circuits Syst. I Regul. Pap. 68(9): 3656-3667 (2021) - [c29]Karlheinz Ochs, Dennis Michaelis, Sebastian Jenderny, Marc-Kevin Szymendera:
Kuramoto Model with Hebbian Learning Mimics Spatial Correlations Causing an Optical Illusion. MWSCAS 2021: 36-39 - [c28]Dennis Michaelis, Karlheinz Ochs, Sebastian Jenderny:
A Memristive Circuit for Gait Pattern Classification Based on Self-Organized Axon Growth. MWSCAS 2021: 162-165 - [c27]Dennis Michaelis, Sebastian Jenderny, Karlheinz Ochs:
A Self-Organizing Gait Pattern Generator Exploiting an Electrical Circuit for Axon Growth. MWSCAS 2021: 166-169 - [c26]Karlheinz Ochs, Bakr Al Beattie, Sebastian Jenderny:
An Ising Machine Solving Max-Cut Problems based on the Circuit Synthesis of the Phase Dynamics of a Modified Kuramoto Model. MWSCAS 2021: 982-985 - 2020
- [j8]Karlheinz Ochs, Dennis Michaelis, Enver Solan:
Towards Wave Digital Memcomputing With Physical Memristor Models. IEEE Trans. Circuits Syst. I Fundam. Theory Appl. 67-I(4): 1092-1102 (2020) - [j7]Karlheinz Ochs, Dennis Michaelis, Enver Solan, Petro Feketa, Alexander Schaum, Thomas Meurer:
Synthesis, Design, and Synchronization Analysis of Coupled Linear Electrical Networks. IEEE Trans. Circuits Syst. 67-I(12): 4521-4532 (2020) - [c25]Karlheinz Ochs, Sebastian Jenderny, Enver Solan:
Anticipation of Irregular Patterns: A Wave Digital Approach. MWSCAS 2020: 313-316 - [c24]Karlheinz Ochs, Dennis Michaelis, Sebastian Jenderny, Hermann Kohlstedt:
Mimicking Neuroplasticity by Memristive Circuits. MWSCAS 2020: 448-451
2010 – 2019
- 2019
- [c23]Karlheinz Ochs, Enver Solan, Dennis Michaelis, Maximilian Herbrechter:
Towards Wave Digital Memcomputing with Physical Memristor Models. ISCAS 2019: 1-4 - [c22]Karlheinz Ochs, Dennis Michaelis, Enver Solan:
Wave Digital Emulation of a Memristive Circuit to Find the Minimum Spanning Tree. MWSCAS 2019: 351-354 - [c21]Karlheinz Ochs, Dennis Michaelis, Enver Solan:
Solving the Longest Path Problem using a HfO2-based Wave Digital Memristor Model. MWSCAS 2019: 355-358 - [c20]Karlheinz Ochs, Enver Solan, Dennis Michaelis, Leon Schmitz:
Towards a Self-Organizing Deciphering System based on a Wave Digital Emulator. MWSCAS 2019: 662-665 - [i7]Petro Feketa, Alexander Schaum, Thomas Meurer, Dennis Michaelis, Karlheinz Ochs:
Synchronization of nonlinearly coupled networks of Chua oscillators. CoRR abs/1904.00484 (2019) - 2018
- [j6]Karlheinz Ochs, Martin Ziegler, Eloy Hernandez-Guevara, Enver Solan, Marina Ignatov, Mirko Hansen, Mahal Singh Gill, Hermann Kohlstedt:
Anticipation of digital patterns. Int. J. Circuit Theory Appl. 46(2): 235-243 (2018) - [j5]Enver Solan, Karlheinz Ochs:
Wave digital emulation of general memristors. Int. J. Circuit Theory Appl. 46(11): 2011-2027 (2018) - [c19]Karlheinz Ochs, Dennis Michaelis, Sebastian Jenderny:
An Optimized Morris-Lecar Neuron Model Using Wave Digital Principles. MWSCAS 2018: 61-64 - [c18]Karlheinz Ochs, Dennis Michaelis, Sebastian Jenderny:
Mimicking Gait Pattern Generators. MWSCAS 2018: 73-76 - [c17]Karlheinz Ochs, Dennis Michaelis:
Neural Network Topology Formation Using Memristive Jaumann Structures. MWSCAS 2018: 660-663 - 2017
- [c16]Karlheinz Ochs, Eloy Hernandez-Guevara, Enver Solan:
Wave digital information anticipator. MWSCAS 2017: 148-151 - [c15]Karlheinz Ochs, Eloy Hernandez-Guevara, Enver Solan:
Wave digital emulation of spike-timing dependent plasticity. MWSCAS 2017: 152-155 - [c14]Enver Solan, Karlheinz Ochs:
Parameter identification of a double barrier memristive device. MWSCAS 2017: 851-854 - [c13]Karlheinz Ochs, Enver Solan:
A consistent modeling of passive memcapacitive systems. MWSCAS 2017: 855-858 - [c12]Tim Poguntke, Davi Duarte de Carvalho Filho, Karlheinz Ochs:
A System-Theoretic View on Breathing Detection Using Chirp Sequence Modulated Radar Sensors. NGCAS 2017: 261-264 - [i6]Enver Solan, Sven Dirkmann, Mirko Hansen, Dietmar Schroeder, Hermann Kohlstedt, Martin Ziegler, Thomas Mussenbrock, Karlheinz Ochs:
An Enhanced Lumped Element Electrical Model of a Double Barrier Memristive Device. CoRR abs/1701.08068 (2017) - [i5]Karlheinz Ochs, Martin Ziegler, Eloy Hernandez-Guevara, Enver Solan, Marina Ignatov, Mirko Hansen, Mahal Singh Gill, Hermann Kohlstedt:
Anticipation of digital patterns. CoRR abs/1704.07102 (2017) - [i4]Enver Solan, Karlheinz Ochs:
Generic Wave Digital Emulation of Memristive Devices. CoRR abs/1709.07873 (2017) - 2016
- [c11]Karlheinz Ochs, Tim Poguntke:
Optimal filter design for signal estimation based on linear time-variant system theory. ISCAS 2016: 1218-1221 - [c10]Karlheinz Ochs, Enver Solan:
Sensitivity analysis of memristors based on emulation techniques. MWSCAS 2016: 1-4 - [c9]Karlheinz Ochs, Enver Solan:
Wave digital emulation of charge-or flux-controlled memristors. MWSCAS 2016: 1-4 - [c8]Karlheinz Ochs, Enver Solan, Sven Dirkmann, Thomas Mussenbrock:
Wave digital emulation of a double barrier memristive device. MWSCAS 2016: 1-4 - [c7]Tim Poguntke, Karlheinz Ochs:
Linear time-variant system identification using FMCW radar systems. MWSCAS 2016: 1-4 - 2014
- [c6]Daniel Frank, Karlheinz Ochs, Aydin Sezgin:
A systematic approach for interference alignment in CSIT-less relay-aided X-networks. WCNC 2014: 1126-1131 - [i3]Anas Chaaban, Karlheinz Ochs, Aydin Sezgin:
Simultaneous Diagonalization: On the DoF Region of the K-user MIMO Multi-way Relay Channel. CoRR abs/1404.2081 (2014) - 2013
- [j4]Karlheinz Ochs:
A note on stability of linear time-variant electrical circuits having constant eigenvalues. Int. J. Circuit Theory Appl. 41(9): 960-971 (2013) - [c5]Anas Chaaban, Karlheinz Ochs, Aydin Sezgin:
The degrees of freedom of the MIMO Y-channel. ISIT 2013: 1581-1585 - [i2]Anas Chaaban, Karlheinz Ochs, Aydin Sezgin:
The Degrees of Freedom of the MIMO Y-channel. CoRR abs/1305.3054 (2013) - [i1]Daniel Frank, Karlheinz Ochs, Aydin Sezgin:
A Systematic Approach for Interference Alignment in CSIT-less Relay-Aided X-Networks. CoRR abs/1309.3446 (2013) - 2012
- [j3]Christiane Leuer, Karlheinz Ochs:
On systematic wave digital modeling of passive hyperbolic partial differential equations. Int. J. Circuit Theory Appl. 40(7): 709-731 (2012)
2000 – 2009
- 2007
- [c4]Karlheinz Ochs:
A Parameterization of Band-Limited Nyquist Pulses. SiPS 2007: 452-456 - 2005
- [j2]Dietrich Fränken, Jörg Ochs, Karlheinz Ochs:
Generation of wave digital structures for networks containing multiport elements. IEEE Trans. Circuits Syst. I Regul. Pap. 52-I(3): 586-596 (2005) - 2003
- [c3]Dietrich Fränken, Jörg Ochs, Karlheinz Ochs:
Generation of wave digital structures for connection networks containing ideal transformers. ISCAS (3) 2003: 240-243 - 2001
- [c2]Dietrich Fränken, Karlheinz Ochs:
Wave digital simulation of nonlinear electrical networks by means of passive Runge-Kutta methods. ISCAS (3) 2001: 469-472 - [c1]Dietrich Fränken, Karlheinz Ochs:
Numerical stability properties of passive Runge-Kutta methods. ISCAS (3) 2001: 473-476 - 2000
- [j1]Karlheinz Ochs, Michael Vollmer:
An extension of Darlington's algorithm for the design of elliptic filters. IEEE Trans. Signal Process. 48(9): 2709-2712 (2000)
Coauthor Index
manage site settings
To protect your privacy, all features that rely on external API calls from your browser are turned off by default. You need to opt-in for them to become active. All settings here will be stored as cookies with your web browser. For more information see our F.A.Q.
Unpaywalled article links
Add open access links from 
to the list of external document links (if available).
Privacy notice: By enabling the option above, your browser will contact the API of unpaywall.org to load hyperlinks to open access articles. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Unpaywall privacy policy.
Archived links via Wayback Machine
For web page which are no longer available, try to retrieve content from the 
of the Internet Archive (if available).
Privacy notice: By enabling the option above, your browser will contact the API of archive.org to check for archived content of web pages that are no longer available. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Internet Archive privacy policy.
Reference lists
Add a list of references from 
, 
, and 
to record detail pages.
load references from crossref.org and opencitations.net
Privacy notice: By enabling the option above, your browser will contact the APIs of crossref.org, opencitations.net, and semanticscholar.org to load article reference information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Crossref privacy policy and the OpenCitations privacy policy, as well as the AI2 Privacy Policy covering Semantic Scholar.
Citation data
Add a list of citing articles from and to record detail pages.
load citations from opencitations.net
Privacy notice: By enabling the option above, your browser will contact the API of opencitations.net and semanticscholar.org to load citation information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the OpenCitations privacy policy as well as the AI2 Privacy Policy covering Semantic Scholar.
OpenAlex data
Load additional information about publications from 
.
Privacy notice: By enabling the option above, your browser will contact the API of openalex.org to load additional information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the information given by OpenAlex.
last updated on 2024-10-07 21:24 CEST by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint
dblp was originally created in 1993 at:
since 2018, dblp has been operated and maintained by:
the dblp computer science bibliography is funded and supported by:
