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Nexxim Simulator > Voltage-Controlled Current Source, Polynomial
Polynomial VCCS Netlist FormatThe format for a polynomial voltage-controlled current source (VCCS) is: Gxxxx out+ out- [VCCS] POLY(N) in1+ in1- [in2+ in2- [in3+ in3-]] [MAX=val] [MIN=val] [SCALE=scale] [M=val] [TC1=val] [TC2=val] [ABS=0|1] p0 [p1 ... pK ] out+ is the positive node and out- is the negative node of the current source. The entry VCCS is the default for the G element type. The entry POLY is required to identify the polynomial VCCS type. The number of input voltage pairs, N, can be 1, 2, or 3. If N is not specified, 1 input is the default. in+ and in- are the N pairs of positive and negative nodes for the control voltages. p0 through pK are the K coefficients for the polynomial function. One coefficient must be provided.
Polynomial VCCS Netlist ExamplesG21 21 0 VCCS POLY(1) 1 0 1.1 2.1 0 3.1 G31 31 0 VCCS POLY(2) 1 0 2 0 1.2 2.2 0 0 0 0 0 0 3.2 0 G41 41 0 VCCS POLY(3) 1 0 2 0 3 0 1.3 2.3 0 0 + 0 0 0 0 0 0 + 0 3.3 0 0 0 0 0 0 0 4.3 NotesThe functional equation for the polynomial VCCS is: I(out+, out-)) = polynomial ´ SCALE ´ M ´ (1 + DT ´ TC1 + DT2 ´ TC2) If the result is less than MIN, I(out+, out-) = MIN If the result is greater than MAX, I(out+, out-) = MAX The polynomial depends on the number of inputs (N) and the number of polynomial coefficients (K). Each polynomial has terms of order (O), the sum of the exponents of the elements in the term. The list of coefficients must include coefficients for every term up to and including the complete group of terms with the highest order in the specified polynomial, using zero coefficients for any intermediate or trailing terms that are not to be computed. When N=1, the polynomial formula has one term each of order O{0, 1, ... K}: p0 + p1 ´ V(in1+, in1-) + ... pK ´ V(in1+, in1-)K For example, to specify a VCCS between nodes 21 and 0 whose output, controlled by the voltagte across nodes 1 and 0, is described by the one-input polynomial 1.1 + 2.1 ´ V(1, 0) + 3.1 ´ V(1, 0)3, the instance statement would set coefficients p0=1.1, p1=2.1, p2=0, and p3=3.1: G21 21 0 VCCS POLY(1) 1 0 1.1 2.1 0 3.1 When N=2, the polynomial formula can have more than one term in each order grouping: O(0) p0 + O(1) p1 ´ V(in1+, in1-) + p2 ´ V(in2+, in2-) + O(2) p3 ´ V(in1+, in1-)2 + p4 ´ V(in1+, in1-) ´ V(in2+, in2-) + p5 ´ V(in2+, in2-)2 + O(3) p6 ´ V(in1+, in1-)3 + p7 ´ V(in1+, in1-)2 ´ V(in2+, in2-) + p8 ´ V(in1+, in1-) ´ V(in2+, in2-)2 + p9 ´ V(in2+, in2-)3 + O(4) ... For example, to specify a VCCS between nodes 31 and 0 whose output, controlled by voltages across node pairs (1,0) and (2,0), is described by the two-input polynomial 1.2 + 2.2 ´ V(1, 0) + 3.2 ´ V(1, 0) ´ V(2, 0)2, the instance statement would set coefficients p0=1.2, p1=2.2, and p8=3.2. Intermediate coefficients p2 through p7 and trailing coefficient p9 are set to 0: G31 31 0 VCCS POLY(2) 1 0 2 0 1.2 2.2 0 0 0 0 0 0 3.2 0 When N=3, the polynomial formula becomes: O(0) p0 + O(1) p1 ´ V(in1+, in1-) + p2 ´ V(in2+, in2-) + p3 ´ V(in3+, in3-) + O(2) p4 ´ V(in1+, in1-)2 + p5 ´ V(in1+, in1-) ´ V(in2+, in2-) + p6 ´ V(in1+, in1-) ´ V(in3+, in3-) + p7 ´ V(in2+, in2-)2 + p8 ´ V(in2+, in2-) ´ V(in3+, in3-) + p9 ´ V(in3+, in3-)2 + O(3) p10 ´ V(in1+, in1-)3 + p11 ´ V(in1+, in1-)2 ´ V(in2+, in2-) + p12 ´ V(in1+, in1-)2 ´ V(in3+, in3-) + p13 ´ V(in1+, in1-) ´ V(in2+, in2-)2 + p14 ´ V(in1+, in1-) ´ V(in2+, in2-) ´ V(in3+, in3-) + p15 ´ V(in1+, in1-) ´ V(in3+, in3-)2 + p16 ´ V(in2+, in2-)3 + p17 ´ V(in2+, in2-)2 ´ V(in3+, in3-) + p18 ´ V(in2+, in2-) ´ V(in3+, in3-)2 + p19 ´ V(in3+, in3-)3 + O(4) ... For example, to specify a VCCS between nodes 41 and 0 whose output, controlled by the voltages across node pairs (1, 0), (2, 0), and (3, 0), is described by the three-input polynomial 1.3 + 2.3 ´ V(1, 0) + 3.3 ´ V(1, 0)2 ´ V(2, 0) + 4.3 ´ V(3, 0)3, the instance statement would set coefficients p0=1.3, p1=2.3, p11=3.3, and p19=4.3. Intermediate coefficients p2 through p10 and p12 through p18 are set to 0 (since p19 is the coefficient for the highest term with order 3, no trailing zeros are needed): G41 41 0 VCCS POLY(3) 1 0 2 0 3 0 1.3 2.3 0 0 + 0 0 0 0 0 0 + 0 3.3 0 0 0 0 0 0 0 4.3 HFSS视频教程 ADS视频教程 CST视频教程 Ansoft Designer 中文教程 |
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