% Digital circuit sizing for an inverter chain. % (a figure is generated) % % This is an example taken directly from the paper: % % Digital circuit optimization via geometrical programming % by Boyd, Kim, Patil, and Horowitz % Operations Research 53(6): 899-932, 2005. % % We consider a chain of N inverters driving a load capacitance CL. % The problem is to find optimal scale factors for the inverter % that minimize the sum of them (area), while obeying constraints % on the maximum delay through the circuit, and minimum and maximum % limits on scale factors. There are no limits on the total power. % (For more details about the inverter chain see sec. 2.1.11 in the paper.) % % minimize sum(x) % s.t. T_j <= Dmax for j an output gate % T_j + d_i <= T_i for j in FI(i) % x_min <= x <= x_max % % where variables are x and T. % Here we use data structures and digital circuit models from the % referenced paper. % % Almir Mutapcic 01/26/06 clear all; close all; %******************************************************************** % problem data %******************************************************************** N = 8; % number of inverters CL = 20; % capacitance load Dmax = 20; % maximum delay through the circuit x_min = 1; % minimum scale factor x_max = 20; % maximum scale factor % primary inputs and primary outputs labels (start with N+1) primary_inputs = [N+1]; primary_outputs = [N+2]; M = N + length( primary_inputs ) + length( primary_outputs ); % fan-in cell array FI{1} = [N+1]; for k = 2:N FI{k} = [k-1]; end FI{N+2} = [N]; % fan-out cell array (compute it from the fan-in cell array) FO = cell(M,1); for gate = [1:N primary_outputs] preds = FI{gate}; for k = 1:length(preds) FO{preds(k)}(end+1) = gate; end end % input and internal capacitance of gates and the driving resistance Cin_norm = ones(N,1); Cint_norm = ones(N,1); Rdrv_norm = ones(N,1); % place extra capacitance before the input of the 5th inverter Cin_norm(5) = 80; % primary output has Cin capacitance (but has no Cload) Cin_po = sparse(M,1); Cin_po(primary_outputs) = CL; % primary input has Cload capacitance (but has no Cin) Cload_pi = sparse(M,1); Cload_pi(primary_inputs) = 1; %******************************************************************** % optimization %******************************************************************** % optimization variables gpvar x(N) % sizes gpvar T(N) % arrival times % input capacitance is an affine function of sizes Cin = Cin_norm.*x; Cint = Cint_norm.*x; % driving resistance is inversily proportional to sizes R = Rdrv_norm./x; % gate delay is the product of its driving resistance and load cap. Cload = posynomial; for gate = 1:N if ~ismember( FO{gate}, primary_outputs ) Cload(gate) = sum( Cin(FO{gate}) ); else Cload(gate) = Cin_po( FO{gate} ); end end Cload = Cload'; % delay D = 0.69*ones(N,1).*R.*( Cint + Cload ); % create timing constraints timing_constr = []; for gate = 1:N if ~ismember( FI{gate}, primary_inputs ) for j = FI{gate} % enforce T_j + D_j <= T_i over all gates j that drive i timing_constr = [timing_constr; D(gate) + T(j) <= T(gate)]; end else % enforce D_i <= T_i for gates i connected to primary inputs timing_constr = [timing_constr; D(gate) <= T(gate)]; end end % circuit delay is the max of arrival times for output gates output_gates = [FI{primary_outputs}]; circuit_delay = max( T(output_gates) ); % collect all the constraints constr = [timing_constr; circuit_delay <= Dmax; x_min*ones(N,1) <= x; x <= x_max*ones(N,1)]; % minimize the sum of scale factors subject to above constraints [obj_value, solution, status] = gpsolve(sum(x), constr); assign(solution); % message about extra capacitance and result display disp(' ') disp(['Note: there is an extra capacitance between the 4th and 5th inverter'... ' in the chain.']) fprintf(1,'\nOptimal scale factors are: \n'), x % plot scale factors and maximum delay for inverter i close all; subplot(2,1,1); plot([1:N],T,'g--',[1:N],T,'bo'); ylabel('maximum delay T') subplot(2,1,2); stem([1:N],x); ylabel('scale factor x') xlabel('inverter stage')