Very low bit rate parametric audio coding

[no abstract

A development study for a short range, low capacity digital microwave link

Includes bibliographical references.A specific request for development of a short-range, low capacity digital microwave transmission system has been received from the South African Dept. Posts and Telecommunications. The aim of this project is to initiate development work by determining the optimum system configuration and modulation technique to meet the design specifications. In addition, it is proposed to develop and construct an I.F. modulator/demodulator module using which simulation tests chosen modulation application may be performed in order to assess the scheme's feasibi1ity in this specific application

Feasibility study for a Scanning Celestial Attitude Determination System /SCADS/ for three axis attitude determination at a Command and Data Acquisition /CDA/ station Final report

Scanning Celestial Attitude Determination System /SCADS/ for three axis attitude determination at Command and Data Acquisition /CDA/ statio

Design and Analysis of OFDM System for Powerline Based Communication

Research on digital communication systems has been greatly developed in the past few years and offers a high quality of transmission in both wired and wireless communication environments. Coupled with advances in new modulation techniques, Orthogonal Frequency Division Multiplexing (OFDM) is a well-known digital multicarrier communication technique and one of the best methods of digital data transmission over a limited bandwidth. The main aim of this research is to design an OFDM modem for powerline-based communication in order to propose and examine a novel approach in comparing the different modulation order, different modulation type, application of Forward Error Correction (FEC) scheme and also application of different noise types and applying them to the two modelled channels, Additive White Gaussian Noise (AWGN) and Powerline modelled channel. This is an attempt to understand and recognise the most suitable technique for the transmission of message or image within a communication system. In doing so, MATLAB and embedded Digital Signal Processing (DSP) systems are used to simulate the operation of virtual transmitter and receiver. The simulation results presented in this project suggest that lower order modulation formats (Binary Phase Shift Keying (BPSK) and 4-Quadrature Amplitude Modulation (QAM)), are the most preferred modulation techniques (in both type and order) for their considerable performance. The results also indicated that, Convolutional Channel Encoding (CCE)-Soft and Block Channel Encoding (BCE)-Soft are by far the best encoding techniques (in FEC type) for their best performance in error detection and correction. Indeed, applying these techniques to the two modelled channels has proven very successful and will be accounted as a novel approach for the transmission of message or image within a powerline based communication system

Tracking and data relay satellite system configuration and tradeoff study. Volume 5: TDRS spacecraft design, part 1

A dual spin stabilized TDR spacecraft design is presented for low data rate (LDR) and medium data rate (MDR) user spacecraft telecommunication relay service. The relay satellite provides command and data return channels for unmanned users together with duplex voice and data communication channels for manned user spacecraft. TDRS/ground links are in the Ku band. Command links are provided at UHF for LDR users and S band for MDR users. Voice communication channels are provided at UHF/VHF for LDR users and at S band for MDR users. The spacecraft is designed for launch on the Delta 2914 with system deployment planned for 1978. This volume contains a description of the overall TDR spacecraft configuration, a detailed description of the spacecraft subsystems, a reliability analysis, and a product effectiveness plan

Space programs summary no. 37-58, volume 3 for the period 1 June - 31 July 1969. Supporting research and advanced development

Review of developments in current engineering and scientific work at JP

Models of learning in the visual system: dependence on retinal eccentricity

In the primary visual cortex of primates relatively more space is devoted to the representation of the central visual field in comparison to the representation of the peripheral visual field. Experimentally testable theories about the factors and mechanisms which may have determined this inhomogeneous mapping may provide valuable insights into general processing principles in the visual system. Therefore, I investigated to which visual situations this inhomogeneous representation of the visual field is well adapted, and which mechanisms could support its refinement and stabilization during individual development. Furthermore, I studied possible functional consequences of the inhomogeneous representation for visual processing at central and peripheral locations of the visual field. Vision plays an important role during navigation. Thus, visual processing should be well adapted to self-motion. Therefore, I assumed that spatially inhomogeneous retinal velocity distributions, caused by static objects during self-motion along the direction of gaze, are transformed on average into spatially homogeneous cortical velocity distributions. This would have the advantage that the cortical mechanisms, concerned with the processing of self-motion, can be identical in their spatial and temporal properties across the representation of the whole visual field. This is the case if the arrangement of objects relative to the observer corresponds to an ellipsoid with the observer in its center. I used the resulting flow field to train a network model of pulse coding neurons with a Hebbian learning rule. The distribution of the learned receptive fields is in agreement with the inhomogeneous cortical representation of the visual field. These results suggest that self motion may have played an important role in the evolution of the visual system and that the inhomogeneous cortical representation of the visual field can be refined and stabilized by Hebbian learning mechanisms during ontogenesis under natural viewing conditions. In addition to the processing of self-motion, an important task of the visual system is the grouping and segregation of local features within a visual scene into coherent objects. Therefore, I asked how the corresponding mechanisms depend on the represented position of the visual field. It is assumed that neuronal connections within the primary visual cortex subserve this grouping process. These connections develop after eye-opening in dependence on the visual input. How does the lateral connectivity depend on the represented position of the visual field? With increasing eccentricity, primary cortical receptive fields become larger and the cortical magnification of the visual field declines. Therefore, I investigated the spatial statistics of real-world scenes with respect to the spatial filter-properties of cortical neurons at different locations of the visual field. I show that correlations between collinearly arranged filters of the same size and orientation increase with increasing filter size. However, in distances relative to the size of the filters, collinear correlations decline more steeply with increasing distance for larger filters. This provides evidence against a homogeneous cortical connectivity across the whole visual field with respect to the coding of spatial object properties. Two major retino-cortical pathways are the magnocellular (M) and the parvocellular (P) pathways. While neurons along the M-pathway display temporal bandpass characteristics, neurons along the P-pathway show temporal lowpass characteristics. The ratio of P- to M-cells is not constant across the whole visual field, but declines with increasing retinal eccentricity. Therefore, I investigated how the different temporal response-properties of neurons of the M- and the P-pathways influence self-organization in the visual cortex, and discussed possible consequences for the coding of visual objects at different locations of the visual field. Specifically, I studied the influence of stimulus-motion on the self-organization of lateral connections in a network-model of spiking neurons with Hebbian learning. Low stimulus velocities lead to horizontal connections well adapted to the coding of the spatial structure within the visual input, while higher stimulus velocities lead to connections which subserve the coding of the stimulus movement direction. This suggests that the temporal lowpass properties of P-neurons subserve the coding of spatial stimulus attributes (form) in the visual cortex, while the temporal bandpass properties of M-neurons support the coding of spatio-temporal stimulus attributes (movement direction). Hence, the central representation of the visual field may be well adapted to the encoding of spatial object properties due to the strong contribution of P-neurons. The peripheral representation may be better adapted to the processing of motion