Genomics is rapidly becoming a multifaceted sub

Genomics is rapidly becoming a multifaceted sub-discipline of biology, and aims to understand: (1) the molecular organization and (2) information content of the entire genome (= the collection of all the genes in a gamete, or the haploid set of chromosomes) and its gene products (the transcriptome and proteome -- see below).¹Genomics includes the development and application of new mapping, sequencing, and computational procedures for the (molecular) analysis of the entire genome.²Genomics has 3 distinct subfields: (a) Structural genomics = the genetic and physical mapping, and sequencing of entire genomes, (b) Functional genomics = the analysis of gene (and non-gene) sequences, particularly all those genes that make RNA (mRNA, tRNA, rRNA, snRNA, etc.), or the transcriptome, and all those genes that make only mRNA for translation into protein, or the proteome, (c) comparative genomics = the comparison of entire genomes from different organisms to understand functional and evolutionary relationships.²

1. An Introduction to Genetic Analysis by A.J.F. Griffiths, J.H. Miller, D.T. Suzuki, R.C. Lewontin, and W.M. Gelbart. 2000. Ch. 14, p. 436. W.H. Freeman and Co., Publishers.
2. Genetics by P.J. Russell. 2002. Ch. 9, p. 220. Benjamin Cummings, Publihsers.
see also: What is Genomics (Genomics is operationally defined as investigations into the structure and function of very large numbers of genes undertaken in a simultaneous fashion.) and Genomics glossaries and taxonomies