Title :
Multi-dimensional approach to high resolution and high speed binary-to-thermometer decoding
Author :
Kyaw, Kyaw ; Geiger, Randall L.
Author_Institution :
Dept. of Electr. & Comput. Eng., Iowa State Univ., Ames, IA, USA
Abstract :
A binary-to-thermometer decoding logic that allows high speed decoding at high resolution is presented. DNL performance of both binary-weighted and thermometer-coded decoding schemes in digital-to-analog conversion is discussed. Other works on binary-to-thermometer decoder are explored. In multi-dimensional decoding, a small decoding circuit is attached to each current cell in a current-steering DAC to minimize the delay caused by the traditionally large combinational binary-to-thermometer decoders. Doing so, a larger number of bits can be decoded using thermometer-coded method without having to sacrifice in decoding speed. This also relaxes the matching requirements between the thermometer-coded current sources and eventually saving silicon area.
Keywords :
analogue circuits; binary codes; codecs; combinational circuits; constant current sources; decoding; digital-analogue conversion; logic design; thermometers; analogue circuits; combinational circuits; current steering DAC; decoding circuit; digital-to-analog conversion; high resolution binary-to-thermometer decoding; high speed binary-to-thermometer decoding; multidimensional decoding; thermometer coded current source; thermometer coded decoding method; Analog circuits; CMOS technology; Code standards; Decoding; Delay; Digital-analog conversion; Fabrication; Logic; Multidimensional signal processing; Silicon;
Conference_Titel :
Microelectronics, 2004. ICM 2004 Proceedings. The 16th International Conference on
Print_ISBN :
0-7803-8656-6
DOI :
10.1109/ICM.2004.1434711
