Hennig, Patrick: On the neural encoding of object information : a model simulation study of the fly lobula plate network. 2011
Inhalt
- 1. Summary
- 2. General introduction and discussion
- 2.1 Scientific Background
- Visual system of the blowfly
- Connections within the lobula plate
- Model abstract level
- Model optimization
- 2.2. Main projects
- Computational principle underlying the FD1-cell’s object preference
- Binocular integration in the circuit presynaptic to the FD1-cell
- Functional analysis on the FD1-circuit
- 2.3. General Discussion & Conclusions
- Predictions
- Functional aspects
- Operating range of the models
- Abstraction level of the models
- Outlook
- 2.4. References
- 3. Distributed Dendritic Processing Facilitates Object Detection: A Computational Analysis on the Visual System of the Fly.
- 3.1. Abstract
- 3.2. Introduction
- 3.3. Methods
- Constraints
- Constraints imposed by the structure of the circuitry
- Characteristic response properties of FD-cells
- Components of the model
- Input organization and receptive fields
- Distributed dendritic interaction as a low pass filter
- Spatial Integration
- Function of synaptic transmission
- Direct Pooled Inhibition Model
- Direct Distributed Inhibition Model
- Indirect Distributed Inhibition Model
- Optimization
- Algorithm
- 3.4. Results
- Direct Pooled Inhibition (DPI)
- Direct Distributed Inhibition (DDI)
- Indirect Distributed Inhibition (IDI)
- Functional Principles
- Small field tuning based on DDI
- Small field tuning based on IDI
- 3.5. Discussion
- The distributed inhibition satisfies all constraints
- Advantages of distributed processing
- Indirect inhibition is less demanding
- Prediction to distinguish indirect and direct inhibition electrophysiologically
- Open problems
- Similarity to lateral inhibition
- 3.6. Acknowledgments
- 3.7. References
- 4. Binocular integration of visual information: a model study on naturalistic optic flow processing.
- 4.1. Abstract
- 4.2. Introduction
- 4.3. Material and Methods
- Stimulus generation and electrophysiology
- Masks
- Animals and electrophysiological recording
- Data analysis
- Models
- Eye model and peripheral processing
- Elementary motion detection
- Spatially integrating elements
- Synaptic transmission
- Local sensitivities
- HS models
- H1 and Hu model
- vCH model
- Optimizing model parameters
- 4.4. Results
- Responses of the vCH-cell to behaviourally generated optic flow
- Contralateral input mediated by the H1-cell
- Contralateral input mediated by Hu-cell
- Ipsilateral input mediated by HS-cells
- Modeling the contribution of input elements to the vCH-cell response
- Model H1
- Model HS
- Model vCH
- Model performance in control flight sequences
- Interactions between different input areas
- 4.5. Discussion
- 4.6. Conclusions
- 4.7. Acknowledgments
- 4.8. Literature
- 5. Neuronal encoding of object and distance information: a model study on naturalistic optic flow processing.
- 5.1. Abstract
- 5.2. Introduction
- 5.3. Methods and Material
- Models
- Eye model and peripheral processing
- Elementary motion detection
- Presynaptic elements
- Synaptic transmission
- Local sensitivities
- Shunting inhibition
- Spatial integration
- Animals and electrophysiological recording
- Stimuli for the model simulations
- Trajectory
- Naturalistic stimulation
- Size dependence
- Test flight ‘object’
- Test flight ‘step’
- Test flight ‘texture dependance’
- Optimization
- 5.4. Results
- Responses to naturalistic stimulation
- Object induced response increments
- Intersaccadic responses
- Model predictions for specific spatial configurations of the environment
- Test flight ‘object’
- Texture dependence
- Test flight ‘step’
- 5.5. Discussion
- Object-induced behavior
- Predictive power for naturalistic stimulation conditions
- Object detection
- Pattern dependent response fluctuations
- Distance coding
- Potential functional significance
- Pursuit of small moving targets
- Operating range of the model
- 5.6. Conclusions
- 5.7. Acknowledgments
- 5.8. Literature
- 6. Acknowledgments