LC oscillator design (GP)

% Boyd, Kim, and Mohan, "Geometric programming and its
% applications to EDA Problems", (DATE Tutorial 2005), pp.102-113.
% Original code by S. Mohan
% Written for CVX by Almir Mutapcic 02/08/06
%
% Designs an LC oscillator consisting of a loop inductor, varactors
% for fine tuning, binary weighted switching capacitors for coarse
% tuning, cross coupled NMOS transistors, and tail current source.
% The optimal LC oscillator design iwith minimum power consumption,
% and limits on phase noise, area, etc... can be formulated as a GP:
%
%   minimize   P
%       s.t.   N <= Nmax, A <= Amax, l >= lmin, etc.
%
% where optimization variables are loop inductor dimensions D,W,
% size of varactor Vc, size of switching caps Csw, width and length
% of transistors Wnmos, Lnmos, bias current Ibias, etc.

%********************************************************************
% problem data
%********************************************************************
Vdd   = 1.2;         % voltage
CL    = 0.2e-12;     % load capcitance
F     = 5e9;         % operating frequency in Hz
omega = 2*pi*F;      % operating freq. in radians

FOff   = 6e5;        % offset frequency for phase noise calculation
LoopGainSpec = 2.0;  % loop gain spec
Vbias  = 0.2;        % non ideality of current mirror

% tuning specs
T         = 0.1;     % +/- tuning range as a normalized value
CvarRatio = 3;       % maximum to minimum value of CVar
CswBits   = 3;
CswSegs   = 2^(CswBits);
CvarCswLSBOverlap = 2;

disp('Generating the optimal tradeoff curve...')

%********************************************************************
% optimization of LC oscillator circuit (with tradeoff curve)
%********************************************************************
% varying phase noise parameter for the tradeoff curve
powers = [];
for PNSpec=0.7e-12:0.2e-12:1e-11
  fprintf('  PNSpec = %5.2f dBc/Hz: ', 10*log10(PNSpec) );
  cvx_begin gp quiet
    % optimization variables
    variable D;        % diameter of loop inductor
    variable W;        % width of loop inductor
    variable SRF;      % self resonance frequency
    variable l;        % length of CMOS transistor
    variable w;        % width of CMOS transistor
    variable I;        % maximum current through CMOS transistor
    variable VOsc;     % differential voltage amplitude
    variable CT;       % total capacitance of oscillator
    variable Csw;      % maximum switching capacitance
    variable Cvar;     % minimum variable capacitance
    variable IBias;    % bias current
    variable CMaxFreq; % capacitor max frequency

    % minimize power = Vdd*IBias;
    minimize( Vdd*IBias )
    subject to
      %*******************************************%
      % loop inductor definitions and constraints %
      %*******************************************%
      SRFSpec  = 3*F;
      omegaSRF = 2*pi*SRF;

      % inductance
      L = 2.1e-06*D^(1.28)*(W)^(-0.25)*(F)^(-0.01);
      % series resistance
      R = 0.1*D/W+3e-6*D*W^(-0.84)*F^(0.5)+5e-9*D*W^(-0.76)*F^(0.75)+0.02*D*W*F;
      % effective capacitance
      C = 1e-11*D+5e-6*D*W;

      % area, tank conductance, and inverse quality factor
      Area = (D+W)^2;
      G    = R/(omega*L)^2;
      invQ = R/(omega*L);

      % loop constraints
      Area <= 0.25e-6;
      W <= 30e-6;
      5e-6 <= W;
      10*W <= D;
      D <= 100*W;
      SRFSpec <= SRF;
      omegaSRF^2*L*C <= 1;

      %****************************************%
      % transistor definitions and constraints %
      %****************************************%
      GM  = 6e-3*(w/l)^0.6*(I/2)^(0.4);
      GD  = 4e-10*(w/l)^0.4*(I/2)^(0.6)*1/l;
      Vgs = 0.34+1e-8/l+800*(I*l/(2*w))^0.7;
      Cgs = 1e-2*w*l;
      Cgd = 1e-9*w;
      Cdb = 1e-9*w;

      % transistor constraints
      2e-6 <= w;
      0.13e-6 <= l;
      l <= 1e-6;

      %***************************************************%
      % overall LC oscillator definitions and constraints %
      %***************************************************%
      invVOsc = (G+GD)/IBias;

      % phase noise
      kT4  = 4*1.38e-23*300;
      kT4G = 2*kT4;
      LoopCurrentNoise = kT4*G;
      TransistorCurrentNoise = 0.5*kT4G*GM;
      PN = 1/(160*(FOff*VOsc*CT)^2)*(LoopCurrentNoise+TransistorCurrentNoise);

      % capacitance
      Cfix = C+0.5*(CL+Cgs+Cdb+4*Cgd); % fixed capacitance
      CDiffMaxFreq = Cfix+0.5*Cvar;

      invLoopGain = (G+0.5*GD)/(0.5*GM);

      % LC oscillator constraints
      PN <= PNSpec;
      omega^2*L*CT == 1;
      omega^2*(1+T)^2*L*CMaxFreq == 1;
      4*T/((1-T^2)^2)*CT <= Csw*(1+CvarCswLSBOverlap/CswSegs);
      Csw*CvarCswLSBOverlap/CswSegs <= 0.5*Cvar*(CvarRatio-1);
      CDiffMaxFreq <= CMaxFreq;
      VOsc+2*Vbias <= 2*Vdd;
      VOsc*invVOsc <= 1;
      invLoopGain*LoopGainSpec <= 1; % loop gain spec
      Vbias+Vgs+IBias/2*R/2 <= Vdd;  % bias constraint spec
      I == IBias;
  cvx_end
  fprintf('min_power = %3.2f mW\n', cvx_optval/1e-3);
  powers = [powers cvx_optval];
end

% plot the tradeoff curve
PNSpec = 0.7e-12:0.2e-12:1e-11;
plot(10*log10(PNSpec),powers/1e-3);
xlabel('Phase Noise (dBc/Hz)')
ylabel('Power (mW)')
disp('Optimal tradeoff curve plotted.')

Generating the optimal tradeoff curve...
  PNSpec = -121.55 dBc/Hz: min_power = 19.00 mW
  PNSpec = -120.46 dBc/Hz: min_power = 11.41 mW
  PNSpec = -119.59 dBc/Hz: min_power = 8.35 mW
  PNSpec = -118.86 dBc/Hz: min_power = 6.44 mW
  PNSpec = -118.24 dBc/Hz: min_power = 5.64 mW
  PNSpec = -117.70 dBc/Hz: min_power = 5.30 mW
  PNSpec = -117.21 dBc/Hz: min_power = 5.02 mW
  PNSpec = -116.78 dBc/Hz: min_power = 4.77 mW
  PNSpec = -116.38 dBc/Hz: min_power = 4.56 mW
  PNSpec = -116.02 dBc/Hz: min_power = 4.38 mW
  PNSpec = -115.69 dBc/Hz: min_power = 4.21 mW
  PNSpec = -115.38 dBc/Hz: min_power = 4.07 mW
  PNSpec = -115.09 dBc/Hz: min_power = 3.93 mW
  PNSpec = -114.81 dBc/Hz: min_power = 3.81 mW
  PNSpec = -114.56 dBc/Hz: min_power = 3.70 mW
  PNSpec = -114.32 dBc/Hz: min_power = 3.60 mW
  PNSpec = -114.09 dBc/Hz: min_power = 3.51 mW
  PNSpec = -113.87 dBc/Hz: min_power = 3.42 mW
  PNSpec = -113.67 dBc/Hz: min_power = 3.34 mW
  PNSpec = -113.47 dBc/Hz: min_power = 3.27 mW
  PNSpec = -113.28 dBc/Hz: min_power = 3.20 mW
  PNSpec = -113.10 dBc/Hz: min_power = 3.13 mW
  PNSpec = -112.92 dBc/Hz: min_power = 3.07 mW
  PNSpec = -112.76 dBc/Hz: min_power = 3.01 mW
  PNSpec = -112.60 dBc/Hz: min_power = 2.96 mW
  PNSpec = -112.44 dBc/Hz: min_power = 2.91 mW
  PNSpec = -112.29 dBc/Hz: min_power = 2.86 mW
  PNSpec = -112.15 dBc/Hz: min_power = 2.81 mW
  PNSpec = -112.01 dBc/Hz: min_power = 2.77 mW
  PNSpec = -111.87 dBc/Hz: min_power = 2.72 mW
  PNSpec = -111.74 dBc/Hz: min_power = 2.68 mW
  PNSpec = -111.61 dBc/Hz: min_power = 2.64 mW
  PNSpec = -111.49 dBc/Hz: min_power = 2.61 mW
  PNSpec = -111.37 dBc/Hz: min_power = 2.57 mW
  PNSpec = -111.25 dBc/Hz: min_power = 2.54 mW
  PNSpec = -111.14 dBc/Hz: min_power = 2.50 mW
  PNSpec = -111.02 dBc/Hz: min_power = 2.47 mW
  PNSpec = -110.92 dBc/Hz: min_power = 2.44 mW
  PNSpec = -110.81 dBc/Hz: min_power = 2.41 mW
  PNSpec = -110.71 dBc/Hz: min_power = 2.38 mW
  PNSpec = -110.60 dBc/Hz: min_power = 2.36 mW
  PNSpec = -110.51 dBc/Hz: min_power = 2.33 mW
  PNSpec = -110.41 dBc/Hz: min_power = 2.31 mW
  PNSpec = -110.32 dBc/Hz: min_power = 2.28 mW
  PNSpec = -110.22 dBc/Hz: min_power = 2.26 mW
  PNSpec = -110.13 dBc/Hz: min_power = 2.23 mW
  PNSpec = -110.04 dBc/Hz: min_power = 2.21 mW
Optimal tradeoff curve plotted.