Direktsamplande digital transciever / Direct sampling digital transceiver

Karlsson, Magnus

January 2002

<p>Master thesis work at ITN (Department of Science and Technology) in the areas of A/D-construction and RF-circuit design. Major goal of project were to research suitable possibilities for implementations of direct conversion in transceivers operating in the 160MHz band, theoretic study followed by development of components in the construction environment Cadence. Suitable A/D- converter and other important parts were selected at the end of the theoretic study. Subsampling technique was applied to make A/D sample requirements more realistic to achieve. Besides lowering requirements on A/D-converter it allows a more simple construction, which saves more components than subsampling adds. Subsampling add extra noise, because of that an A/D-converter based on the RSD algorithm was chosen to improve error rate. To achieve high bit-processing rate compared to the used number of transistors, pipeline structure were selected as conversion method. The receiver was that part which gained largest attention because it’s the part which is most interesting to optimise. A/D-conversion is more difficult to construct than D/A conversion, besides there’s more to gain from eliminating mixers in the receiver than in the transmitter.</p>

Electronics

A/D-omvandlare

D/A-omvandlare

direktsampling

subsampling

transciever

RSD

Redundant Signed Digit

pipeline

A/D-converter

D/A-converter

direct-conversion

transceiver

Elektronik

Electronics

Elektronik

Direktsamplande digital transciever / Direct sampling digital transceiver

Karlsson, Magnus

January 2002

Master thesis work at ITN (Department of Science and Technology) in the areas of A/D-construction and RF-circuit design. Major goal of project were to research suitable possibilities for implementations of direct conversion in transceivers operating in the 160MHz band, theoretic study followed by development of components in the construction environment Cadence. Suitable A/D- converter and other important parts were selected at the end of the theoretic study. Subsampling technique was applied to make A/D sample requirements more realistic to achieve. Besides lowering requirements on A/D-converter it allows a more simple construction, which saves more components than subsampling adds. Subsampling add extra noise, because of that an A/D-converter based on the RSD algorithm was chosen to improve error rate. To achieve high bit-processing rate compared to the used number of transistors, pipeline structure were selected as conversion method. The receiver was that part which gained largest attention because it’s the part which is most interesting to optimise. A/D-conversion is more difficult to construct than D/A conversion, besides there’s more to gain from eliminating mixers in the receiver than in the transmitter.

Electronics

A/D-omvandlare

D/A-omvandlare

direktsampling

subsampling

transciever

RSD

Redundant Signed Digit

pipeline

A/D-converter

D/A-converter

direct-conversion

transceiver

Elektronik

Electronics

Elektronik

Measurements, Estimations and Calibration with a Fully Digital Array

Magnér, Oscar

January 2023

In modern digital communication, transmission and reception of information through electromagnetic signals requires digital devices that can process high data rates accurately despite being located in information heavy environments. One type of antenna receiver is the digital antenna array, which can steer its lobes electronically to increase or decrease sensitivity in specific directions. A rather recently developed system is the Wideband Digital Array Receiver, developed at Saab Surveillance in Järfälla and referred to as WiDAR. The implementations and possibilities of WiDAR are broad, but no matter its future applications, calibration is an essential feature to ensure truthful reception of data. Any type of electronic system risks errors due to hardware imperfections. The aim of this thesis is to explore and reduce these errors. Measurements with WiDAR were performed in a manner such that some of the intercepted signals were transmitted from a far away located FM and TV-mast. The data was then used to retrieve weights by calculating their relative transfer function, which were applied to calibrate all channels in the antenna array towards a chosen reference channel. These weights could then be on any accumulated set of data measured by WiDAR with hopes to compensate errors in both phase and magnitude. The results show that reducing errors this way was possible, working slightly better when calibrating phase than calibrating magnitude. If more advanced calibration is deemed necessary, further measurements could be performed to investigate where errors or variations occur by isolating different parts of the system. The calibration method used could be further developed by adding an online calibration procedure, meaning relative transfer functions are calculated in real time when performing measurements.

WiDAR

signal processing

digital array

broadband antenna

array antenna

antenna

calibration

direct sampling

antenn

bredbandig

digital array

array antenn

direktsampling

signalbehandling

kalibrering

WiDAR

Saab AB

SAAB

Signal Processing

Signalbehandling