Dimensioning approach for data networks

What is claimed is: 1. A method for dimensioning a downstream data network, comprising: determining a total amount of downstream Data Over Cable Service Interface Specification version 3.1 (DOCSIS 3.1) occupied spectrum in a node; determining unused spectrum and unusable spectrum within a total occupied spectrum of the downstream data network; examining an i-th channel; collecting physical link channel (PLC) data; collecting traffic data; determining time efficiency based on cyclic prefix, net symbol period, the collected PLC data and the collected traffic data; determining a modulated bandwidth and storing an upper bound on a number of subcarriers in a temporary variable “S”; determining an upper and a lower active subcarrier frequency based on one or more of an occupied bandwidth, a guardband and an encompassed bandwidth, which is an upper edge active subcarrier frequency minus a lower edge active subcarrier frequency; updating the temporary variable “S” based on the upper and the lower active subcarrier frequencies and further by subtracting (1) excluded subcarriers, (2) excluded bands converted to subcarriers, (3) continuous pilots that are not in 6 MHz PLC, (4) 8 continuous pilots that are in 6 MHz PLC, (5) staggered/scattered pilots in the 6 MHz PLC; determining a number of PLC subcarriers; calculating a frequency efficiency by dividing the updated temporary variable “S” by the occupied bandwidth; determining available raw bits for each profile/symbol using profile bit loading data; determining a number of effective bits available for each profile/symbol based on the available raw bits for each profile/symbol adjusted by forward error correction (FEC) data; determining an average number of symbols per profile cycle to estimate a number of full and shortened codewords for each profile based on a number of profiles, a volume traffic consumption per profile, and a profile cycle duration; adjusting the number of effective bits available for each profile/symbol after including a normal cyclic prefix (NCP) overhead based on the number of full and shortened codewords, a number of NCP messages, and a number of subcarriers used for the NCP messages; obtaining an effective efficiency in bits per second per Hertz (b/s/Hz) in each of the profiles based on the number of effective bits in a profile multiplied by the time efficiency and divided by a product of the occupied bandwidth and symbols/profile; and determining a profile throughput in bits per second by multiplying the effective efficiency in each profile by the occupied bandwidth.