def optimizePC(channel, noiseIfPower, rate, linkBandwidth, pMax, p0, m, verbosity=0): ''' Uses channel values, PHY parameters and power consumption characteristics to find minimal resource allocation. Returns resource allocation, objective value and IPOPT status. Input: channel - 3d array. 0d users, 1d n_tx, 2d n_rx noiseIfPower - total noise power over the linkbandwidth rate - target rate in bps pMax - maximum allowed transmission power p0 - power consumption at zero transmission (not sleep) m - power consumption load factor verbosity - IPOPT verbosity level Output: obj - solution objective value solution - resource share per user status - IPOPT status ''' # the channel dimensions tell some more parameters users = channel.shape[0] n_tx = channel.shape[1] n_rx = channel.shape[2] # preparing IPOPT parameters nvar = users # for readability x_L = zeros((nvar), dtype=float_) * 0.0 x_U = ones((nvar), dtype=float_) * 1.0 ncon = nvar + 1 # transmit power constraints and the unit sum g_L = zeros(1+nvar) # unit sum and all power constraints g_L[0] = 1. g_U = pMax * ones(1+nvar) # unit sum and all power constraints g_U[0] = 1. nnzj = nvar * (1+nvar) nnzh = 0 #used? x0 = repeat([1./(nvar+1)],nvar) # Starting point # IPOPT requires single parameter functions if n_tx is 2 and n_rx is 2: eval_f = lambda mus: optimMinPow2x2.eval_f(mus, noiseIfPower, channel, rate, linkBandwidth, p0, m) eval_grad_f = lambda mus: optimMinPow2x2.eval_grad_f(mus, noiseIfPower, channel, rate, linkBandwidth, p0, m) eval_g = lambda mus: optimMinPow2x2.eval_g(mus, noiseIfPower, channel, rate, linkBandwidth) eval_jac_g = lambda mus, flag: optimMinPow2x2.eval_jac_g(mus, noiseIfPower, channel, rate, linkBandwidth, flag) else: raise NotImplementedError # other combinations may be needed later # Call solve() pyipopt.set_loglevel(min([2,verbosity])) # verbose nlp = pyipopt.create(nvar, x_L, x_U, ncon, g_L, g_U, nnzj, nnzh, eval_f, eval_grad_f, eval_g, eval_jac_g) #nlp.int_option("max_iter", 3000) #nlp.num_option("tol", 1e-8) #nlp.num_option("acceptable_tol", 1e-2) #nlp.int_option("acceptable_iter", 0) nlp.str_option("derivative_test", "first-order") nlp.str_option("derivative_test_print_all", "no") #nlp.str_option("print_options_documentation", "yes") nlp.int_option("print_level", min([verbosity,12])) # maximum is 12 nlp.str_option("print_user_options", "yes") solution, zl, zu, obj, status = nlp.solve(x0) nlp.close() return obj, solution, status
def test_eval_g(self): """docstring for test_eval_g""" ans = optimMinPow2x2.eval_g(self.x0, self.noisepower, self.H, self.rate, self.linkBandwidth) answer = np.array([ 0.3, 59.16385275, 27.62516375, 41.22583897]) np.testing.assert_array_almost_equal(ans, answer)
def optimizePC(channel, noiseIfPower, rate, linkBandwidth, pMax, p0, m, verbosity=0): ''' Uses channel values, PHY parameters and power consumption characteristics to find minimal resource allocation. Returns resource allocation, objective value and IPOPT status. Input: channel - 3d array. 0d users, 1d n_tx, 2d n_rx noiseIfPower - total noise power over the linkbandwidth rate - target rate in bps pMax - maximum allowed transmission power p0 - power consumption at zero transmission (not sleep) m - power consumption load factor verbosity - IPOPT verbosity level Output: obj - solution objective value solution - resource share per user status - IPOPT status ''' # the channel dimensions tell some more parameters users = channel.shape[0] n_tx = channel.shape[1] n_rx = channel.shape[2] # preparing IPOPT parameters nvar = users # for readability x_L = zeros((nvar), dtype=float_) * 0.0 x_U = ones((nvar), dtype=float_) * 1.0 ncon = nvar + 1 # transmit power constraints and the unit sum g_L = zeros(1 + nvar) # unit sum and all power constraints g_L[0] = 1. g_U = pMax * ones(1 + nvar) # unit sum and all power constraints g_U[0] = 1. nnzj = nvar * (1 + nvar) nnzh = 0 #used? x0 = repeat([1. / (nvar + 1)], nvar) # Starting point # IPOPT requires single parameter functions if n_tx is 2 and n_rx is 2: eval_f = lambda mus: optimMinPow2x2.eval_f(mus, noiseIfPower, channel, rate, linkBandwidth, p0, m) eval_grad_f = lambda mus: optimMinPow2x2.eval_grad_f( mus, noiseIfPower, channel, rate, linkBandwidth, p0, m) eval_g = lambda mus: optimMinPow2x2.eval_g(mus, noiseIfPower, channel, rate, linkBandwidth) eval_jac_g = lambda mus, flag: optimMinPow2x2.eval_jac_g( mus, noiseIfPower, channel, rate, linkBandwidth, flag) else: raise NotImplementedError # other combinations may be needed later # Call solve() pyipopt.set_loglevel(min([2, verbosity])) # verbose nlp = pyipopt.create(nvar, x_L, x_U, ncon, g_L, g_U, nnzj, nnzh, eval_f, eval_grad_f, eval_g, eval_jac_g) #nlp.int_option("max_iter", 3000) #nlp.num_option("tol", 1e-8) #nlp.num_option("acceptable_tol", 1e-2) #nlp.int_option("acceptable_iter", 0) nlp.str_option("derivative_test", "first-order") nlp.str_option("derivative_test_print_all", "no") #nlp.str_option("print_options_documentation", "yes") nlp.int_option("print_level", min([verbosity, 12])) # maximum is 12 nlp.str_option("print_user_options", "yes") solution, zl, zu, obj, status = nlp.solve(x0) nlp.close() return obj, solution, status
def test_eval_g(self): """docstring for test_eval_g""" ans = optimMinPow2x2.eval_g(self.x0, self.noisepower, self.H, self.rate, self.linkBandwidth) answer = np.array([0.3, 59.16385275, 27.62516375, 41.22583897]) np.testing.assert_array_almost_equal(ans, answer)