D/A převodník pro audio s externím ovládáním pomocí mikrokontroléru / Audio D/A converter with external control using microcontroller

Špaček, Jan

January 2012

This diploma thesis deals with the design of a laboratory measurement tool with ADC converter for audio and low frequency signals. In the introduction part a theoretical background of the ADC and DAC conversions are outlined. In the next chapters the technical solution of the laboratory converter is presented, including DAC with integrated circuit AD1852 and completed with digital audio receiver CS8416. This circuit secures compatibility with external audio devices with digital interfaces, like SPDIF or AES3. The digital receiver and audio DAC are added with serial communication interface for setup of the most audio and input parameters. This setup is operated by external microcontroller ATmega32 and original firmware. The thesis contains block diagram and schematic layout of the laboratory converter, including complete technical documentation for the construction and design.

D/A převodník pro audio s externím ovládáním pomocí mikrokontroléru / Audio D/A converter with external control using microcontroller

Špaček, Jan

January 2012

This diploma thesis is devoted to the design of a laboratory measurement tool with DAC converter for audio and low frequency signals. In the introduction part a theoretical background of the ADC and DAC conversions are outlined. In the next chapters the technical solution of the laboratory converter is presented, including DAC with integrated circuit AD1852 and completed with digital audio receiver CS8416. This circuit secures compatibility with external audio devices with digital interfaces, like SPDIF or AES3. The digital receiver and audio DAC are added with serial communication interface for setup of the most audio and input parameters. This setup is operated by external microcontroller ATmega32 and original firmware. The thesis presents block diagram and schematic layout of the laboratory converter, including complete technical documentation for the construction and design.

Parameterizable Channelized Wideband Digital Receiver for High Update Rate

Buxa, Peter E.

30 July 2007

No description available.

Wideband Receiver

Digital Receiver

Electronic Warfare Receiver

Hardware-Based FFT

Polyphase DFT

Frequency Domain Decimation

Frequency Channelization

FFT

Design and Performance Evaluation of 1 Giga Hertz Wideband Digital Receiver

George, Kiranraj

31 July 2007

No description available.

wideband digital receiver

two-signal instantaneous dynamic range

receiver signal processing

Kaiser Window function

compensation technique

spectral leakage

Monobit receiver

high precision spectral estimation

Receiver-On-a-Chip

High Spurious-Free Dynamic Range Digital Wideband Receiver for Multiple Signal Detection and Tracking

Sarathy, Vivek

18 December 2007

No description available.

Microwave receiver

digital receiver

discrete Fourier transforms

signal detection

dynamic kernel function

fast Fourier transform (FFT)

signal detection

spurious-free dynamic range (SFDR).

Implementace softwarového rádia do FPGA / Implementation of software radio into FPGA

Šrámek, Petr

January 2009

The common objective of this project is implementation of software defined radio (SDR) into FPGA. The text contains review and comparison of several hardware concepts intended for SDRs implementation then the methods for digital implementation of various components of radios as the filters, mixers and others are mentioned. Part of the text introduces used hardware platform and describes software support for designing, simulations and implementation into hardware. Significant part of project describes complex of external hardware components as filter, amplifier and control panel designed and built within the project realization. But the main part of project demonstrates design of the software solution of radio receiver. There is specified architecture of radio for FM broadcast receiving, next the more complex systems with carrier recovery algorithm are presented. These systems are able to work with AM, BPSK and QPSK modulations. It is possible to implement all these receivers into hardware and verify their operation. The practical laboratory theme has been outlined within the project run.