Schneider G.: Messages of oscillatory correlograms - a spike train model. Neural Computation (in press)
Willasch A., Schneider G., Reincke B.S., Shayegi N., Kreyenberg H., Ku-Ci S., Weber G., van der Reijden B., Niethammer D., Klingebiel T. & Bader P. Characterisation of chimerism by sequence polymorphism systems for quantitative real time polymerase chain reaction -- high informativity and sensitivity as well as excellent reproducibility and precision of measurement. Lab. Hematology (in press)
Schneider G., Havenith M.N., Nikolic D. (2006): Spatio-temporal structure in large neuronal networks detected from cross correlation. Neural Computation, Vol. 18(10), pp. 2387-2413 preprint
Schneider G., Nikolic D. (2006): Detection and assessment of near-zero delays in neuronal spiking activity. Journal of Neuroscience Methods Vol. 152, pp. 97-106 preprint
Schneider G. (2006): Stochastic models for near-synchronous neuronal firing activity, PhD Thesis
Havenith M.N., Schneider G., Singer W., Nikolic D.: Milliseconds matter: Stimulus information is encoded in the precise relative timing of action potentials in cat visual cortex. Program No. 855.5. 2005 Abstract Viewer/Itinerary Planner. Washington, DC: Society for Neuroscience, 2005. Online.
Nikolic D., Schneider G., Havenith M.N., Singer W.: Short time delays
in neuronal activity depend on stimulus properties.
Program No. 490.8. 2004
Abstract Viewer/Itinerary Planner. Washington, DC: Society for Neuroscience, 2004. Online.
Schneider G., Grün S. (2003): Analysis of higher-order correlations in multiple parallel processes. Neurocomputing, 52-54, pp.771-777 pdf
Schneider G. (2002): Analysis of Higher-Order Coincident Activity in Multiple Parallel Processes, Diploma Thesis
2007
March: DAGStat, University Bielefeld:
Leaning to apply statistics - the statistical practicum in Frankfurt
2006
June: FSPM-Kolloquium, University Bielefeld:
A stochastic model for near-synchronous neuronal firing activity.
March: Frankfurter Stochastik-Tage, Goethe University Frankfurt/Main:
A stochastic model for near-synchronous neuronal firing activity.
March: Meeting Computational Neuroscience, AG Bioinformatik, Goethe University Frankfurt/Main:
Beyond coincidence: Near-synchronous neuronal firing activity.
2005
February: Max-Planck-Institute for
brain
research, Dept. Neurophysiology, Ringberg
Seminar:
How spike train properties shape cross correlation
functions
2004
April: Max-Planck-Institute for brain research, Dept. Neurophysiology, Ringberg
Seminar:
Linear temporal structure of neuronal discharges and its stimulus-dependent
dynamics
June: Johannes
Gutenberg University, Mainz, Dept. Mathematics:
Analysis of
higher-order coincident activity in multiple parallel processes
September: Freie
Univerität Berlin, Institute for Biology-Neurobiology:
Temporal
structure of near-zero cross correlation shifts
November: JWG-University Frankfurt,
Dept. Biology and Computer Science:
Precise measurement and temporal
structure
of preferred delays in neuronal firing activity
December: Max-Planck-Institute for
brain
research, Dept. Neurophysiology:
Further developments in statistical
methods
for studying phase shifts in CC functions
2002
December: Max-Planck-Institute for mathematics in
the sciences, Leipzig:
Analysis of higher-order coincident activity in multiple parallel processes