[4yp.git] / CDCompensation.m

function yCDComp = CDCompensation(y, D, lambda, z, Tsamp)
  %% Chromatic dispersion compensation.
  %% Params:
  %%  - y: received waveform with CD
  %%  - D: dispersion coefficient (ps / (nm km))
  %%  - lambda: wavelength (nm)
  %%  - z: length of fibre (km)
  %%  - Tsamp: sampling time (s)
  %% Output:
  %%  - yCDComp: y after performing CD compensation

  %% Convert everything to SI base units
  c = 299792458; % m/s
  D = D * 1e-6; % s/m^2
  lambda = lambda * 1e-9; % m
  z = z * 1e3; % m

  %% Implementing Eq. (9) in [1].
  N = 2 * floor(abs(D) * lambda^2 * z / (2 * c * Tsamp^2)) + 1;
  k = -floor(N / 2) : floor(N / 2);

  % h: FIR filter
  h = sqrt(j * c * Tsamp^2 / (D * lambda^2 * z)) * ...
      exp(-j * pi * c * Tsamp^2 * k .^ 2 / (D * lambda^2 * z));

  yCDComp = upfirdn(y, h);
  yCDComp = yCDComp(N:end); % truncate filter transients
end
%% References
%% [1]: S.J. Savory, Digital filters for coherent optical receivers, 2008.
Commit	Line	Data
1eeb62fb AIL	1	function yCDComp = CDCompensation(y, D, lambda, z, Tsamp)
	2	%% Chromatic dispersion compensation.
	3	%% Params:
	4	%% - y: received waveform with CD
	5	%% - D: dispersion coefficient (ps / (nm km))
	6	%% - lambda: wavelength (nm)
	7	%% - z: length of fibre (km)
	8	%% - Tsamp: sampling time (s)
	9	%% Output:
	10	%% - yCDComp: y after performing CD compensation
	11
	12	%% Convert everything to SI base units
	13	c = 299792458; % m/s
	14	D = D * 1e-6; % s/m^2
	15	lambda = lambda * 1e-9; % m
	16	z = z * 1e3; % m
	17
	18	%% Implementing Eq. (9) in [1].
	19	N = 2 * floor(abs(D) * lambda^2 * z / (2 * c * Tsamp^2)) + 1;
	20	k = -floor(N / 2) : floor(N / 2);
	21
	22	% h: FIR filter
	23	h = sqrt(j * c * Tsamp^2 / (D * lambda^2 * z)) * ...
	24	exp(-j * pi * c * Tsamp^2 * k .^ 2 / (D * lambda^2 * z));
	25
	26	yCDComp = upfirdn(y, h);
	27	yCDComp = yCDComp(N:end); % truncate filter transients
	28	end
	29	%% References
	30	%% [1]: S.J. Savory, Digital filters for coherent optical receivers, 2008.