2nd Library
GPA.cpp@1:b54eb3e24d2d, 2021-02-25 (annotated)
- Committer:
- altb2
- Date:
- Thu Feb 25 20:28:27 2021 +0000
- Revision:
- 1:b54eb3e24d2d
- Parent:
- 0:a201a6cd4c0c
- Child:
- 4:db615f5fa407
.
Who changed what in which revision?
User | Revision | Line number | New contents of line |
---|---|---|---|
altb2 | 0:a201a6cd4c0c | 1 | /* |
altb2 | 1:b54eb3e24d2d | 2 | GPA: Frequency point wise gain and phase analyser to measure a frequency respone function (FRF) of a dynamical system |
altb2 | 0:a201a6cd4c0c | 3 | |
altb2 | 0:a201a6cd4c0c | 4 | Hint: If the plant has a pole at zero, is unstable or weakly damped the measurement has to be perfomed |
altb2 | 0:a201a6cd4c0c | 5 | in closed loop (this is NOT tfestimate, the algorithm is based on the one point DFT). |
altb2 | 1:b54eb3e24d2d | 6 | Assumption: The system is and remains at the desired steady state when the measurment starts |
altb2 | 1:b54eb3e24d2d | 7 | |
altb2 | 1:b54eb3e24d2d | 8 | Note: The amplitude drops with 1/fexc, if you're using Axc1 = Aexc0/fMax then d/dt exc = const., |
altb2 | 1:b54eb3e24d2d | 9 | this is recommended if your controller does not have a rolloff. If a desired frequency point |
altb2 | 1:b54eb3e24d2d | 10 | is not measured (could not be reached) try to increase Nmeas. |
altb2 | 1:b54eb3e24d2d | 11 | |
altb2 | 0:a201a6cd4c0c | 12 | |
altb2 | 0:a201a6cd4c0c | 13 | Instantiate option 0: ("Not a Jedi yet" users, for logarithmic equaly spaced frequency points) |
altb2 | 1:b54eb3e24d2d | 14 | |
altb2 | 0:a201a6cd4c0c | 15 | GPA(float fMin, float fMax, int NfexcDes, float Aexc0, float Aexc1, float Ts) |
altb2 | 1:b54eb3e24d2d | 16 | |
altb2 | 0:a201a6cd4c0c | 17 | fMin: Minimal desired frequency that should be measured in Hz |
altb2 | 0:a201a6cd4c0c | 18 | fMax: Maximal desired frequency that should be measured in Hz |
altb2 | 0:a201a6cd4c0c | 19 | NfexcDes: Number of logarithmic equaly spaced frequency points between fMin and fMax |
altb2 | 0:a201a6cd4c0c | 20 | Aexc0: Excitation amplitude at fMin |
altb2 | 0:a201a6cd4c0c | 21 | Aexc1: Excitation amplitude at fMax |
altb2 | 0:a201a6cd4c0c | 22 | Ts: Sampling time in sec |
altb2 | 1:b54eb3e24d2d | 23 | |
altb2 | 0:a201a6cd4c0c | 24 | Default values are as follows: |
altb2 | 1:b54eb3e24d2d | 25 | int NperMin = 3; |
altb2 | 1:b54eb3e24d2d | 26 | int NmeasMin = (int)ceil(1.0f/Ts); |
altb2 | 1:b54eb3e24d2d | 27 | int Nstart = (int)ceil(3.0f/Ts); |
altb2 | 1:b54eb3e24d2d | 28 | int Nsweep = (int)ceil(0.0f/Ts); |
altb2 | 0:a201a6cd4c0c | 29 | |
altb2 | 0:a201a6cd4c0c | 30 | Instantiate option 1: ("Jedi or Sith Lord", for logarithmic equaly spaced frequency points) |
altb2 | 1:b54eb3e24d2d | 31 | |
altb2 | 1:b54eb3e24d2d | 32 | GPA(float fMin, float fMax, int NfexcDes, int NperMin, int NmeasMin, float Ts, float Aexc0, float Aexc1, int Nstart, int Nsweep) |
altb2 | 1:b54eb3e24d2d | 33 | |
altb2 | 0:a201a6cd4c0c | 34 | fMin: Minimal desired frequency that should be measured in Hz |
altb2 | 0:a201a6cd4c0c | 35 | fMax: Maximal desired frequency that should be measured in Hz |
altb2 | 0:a201a6cd4c0c | 36 | NfexcDes: Number of logarithmic equaly spaced frequency points |
altb2 | 0:a201a6cd4c0c | 37 | NperMin: Minimal number of periods that are used for each frequency point |
altb2 | 0:a201a6cd4c0c | 38 | NmeasMin: Minimal number of samples that are used for each frequency point |
altb2 | 0:a201a6cd4c0c | 39 | Ts: Sampling time in sec |
altb2 | 0:a201a6cd4c0c | 40 | Aexc0: Excitation amplitude at fMin |
altb2 | 0:a201a6cd4c0c | 41 | Aexc1: Excitation amplitude at fMax |
altb2 | 1:b54eb3e24d2d | 42 | Nstart: Minimal number of samples to sweep to the first frequency point (can be equal 0) |
altb2 | 1:b54eb3e24d2d | 43 | Nsweep: Minimal number of samples to sweep from freq. point to freq. point (can be equal 0) |
altb2 | 1:b54eb3e24d2d | 44 | |
altb2 | 0:a201a6cd4c0c | 45 | |
altb2 | 0:a201a6cd4c0c | 46 | Instantiate option 2: (for a second, refined frequency grid measurement) |
altb2 | 1:b54eb3e24d2d | 47 | |
altb2 | 1:b54eb3e24d2d | 48 | GPA(float f0, float f1, float *fexcDes, int NfexcDes, int NperMin, int NmeasMin, float Ts, float Aexc0, float Aexc1, int Nstart, int Nsweep) |
altb2 | 1:b54eb3e24d2d | 49 | |
altb2 | 0:a201a6cd4c0c | 50 | f0: Frequency point for the calculation of Aexc0 in Hz (should be chosen like in the first measurement) |
altb2 | 0:a201a6cd4c0c | 51 | f1: Frequency point for the calculation of Aexc1 in Hz (should be chosen like in the first measurement) |
altb2 | 0:a201a6cd4c0c | 52 | *fexcDes: Sorted frequency point array in Hz |
altb2 | 0:a201a6cd4c0c | 53 | NfexcDes: Length of fexcDes |
altb2 | 1:b54eb3e24d2d | 54 | |
altb2 | 0:a201a6cd4c0c | 55 | For the other parameters see above. |
altb2 | 0:a201a6cd4c0c | 56 | |
altb2 | 0:a201a6cd4c0c | 57 | Instantiate option 3: (for an arbitary but sorted frequency grid measurement) |
altb2 | 1:b54eb3e24d2d | 58 | |
altb2 | 1:b54eb3e24d2d | 59 | GPA(float *fexcDes, int NfexcDes, int NperMin, int NmeasMin, float Ts, float Aexc0, float Aexc1, int Nstart, int Nsweep) |
altb2 | 1:b54eb3e24d2d | 60 | |
altb2 | 0:a201a6cd4c0c | 61 | *fexcDes: Sorted frequency point array in Hz |
altb2 | 0:a201a6cd4c0c | 62 | Aexc0: Excitation amplitude at fexcDes[0] |
altb2 | 0:a201a6cd4c0c | 63 | Aexc1: Excitation amplitude at fexcDes[NfexcDes-1] |
altb2 | 0:a201a6cd4c0c | 64 | NfexcDes: Length of fexcDes |
altb2 | 1:b54eb3e24d2d | 65 | |
altb2 | 0:a201a6cd4c0c | 66 | For the other parameters see above. |
altb2 | 0:a201a6cd4c0c | 67 | |
altb2 | 1:b54eb3e24d2d | 68 | |
altb2 | 0:a201a6cd4c0c | 69 | Block diagram: |
altb2 | 0:a201a6cd4c0c | 70 | |
altb2 | 0:a201a6cd4c0c | 71 | w (const.) exc(2) C: controller |
altb2 | 0:a201a6cd4c0c | 72 | | | P: plant |
altb2 | 0:a201a6cd4c0c | 73 | v e v |
altb2 | 0:a201a6cd4c0c | 74 | exc(1) --> o ->| C |--->o------->| P |----------> out (y) |
altb2 | 0:a201a6cd4c0c | 75 | ^ - | | |
altb2 | 0:a201a6cd4c0c | 76 | | --> inp (u) | exc (R): excitation signal |
altb2 | 0:a201a6cd4c0c | 77 | | | inp (U): input plant |
altb2 | 0:a201a6cd4c0c | 78 | -------------------------------- out (Y): output plant |
altb2 | 1:b54eb3e24d2d | 79 | |
altb2 | 1:b54eb3e24d2d | 80 | |
altb2 | 0:a201a6cd4c0c | 81 | Pseudo code for an open loop measurement: |
altb2 | 0:a201a6cd4c0c | 82 | |
altb2 | 0:a201a6cd4c0c | 83 | - Measuring the plant P = Gyu = Gyr: |
altb2 | 1:b54eb3e24d2d | 84 | |
altb2 | 0:a201a6cd4c0c | 85 | u = w + exc; |
altb2 | 0:a201a6cd4c0c | 86 | ... write output u here! it follows exc(k+1) ... |
altb2 | 0:a201a6cd4c0c | 87 | exc = Wobble(exc, y); |
altb2 | 1:b54eb3e24d2d | 88 | |
altb2 | 0:a201a6cd4c0c | 89 | Closed loop FRF calculus with a stabilizing controller C: |
altb2 | 1:b54eb3e24d2d | 90 | S = 1/(1 + C*P); % ( exc1 -> e , 1/(1 + C*P) ) sensitivity, contr. error rejection, robustness (1/max|S|) |
altb2 | 1:b54eb3e24d2d | 91 | T = 1 - S; % ( w -> y , C*P/(1 + C*P) ) compl. sensitivity, tracking performance |
altb2 | 1:b54eb3e24d2d | 92 | CS = C*S; % ( exc1 -> u , C/(1 + C*P) ) control effort, disturbance plant output on plant input |
altb2 | 1:b54eb3e24d2d | 93 | PS = P*S; % ( exc2 -> y , P/(1 + C*P) ) compliance, disturbance plant input on plant output |
altb2 | 0:a201a6cd4c0c | 94 | |
altb2 | 0:a201a6cd4c0c | 95 | |
altb2 | 0:a201a6cd4c0c | 96 | Pseudo code for a closed loop measurement with stabilizing controller C: |
altb2 | 0:a201a6cd4c0c | 97 | |
altb2 | 1:b54eb3e24d2d | 98 | Excitation at excitation input (1): |
altb2 | 1:b54eb3e24d2d | 99 | |
altb2 | 0:a201a6cd4c0c | 100 | - Measuring the plant P = Gyu and the closed loop tf T = PC/(1 + PC) = Gyr: |
altb2 | 1:b54eb3e24d2d | 101 | |
altb2 | 0:a201a6cd4c0c | 102 | u = C(w - y + exc); |
altb2 | 0:a201a6cd4c0c | 103 | ... write output u here! it follows exc(k+1) ... |
altb2 | 0:a201a6cd4c0c | 104 | exc = Wobble(u, y); |
altb2 | 1:b54eb3e24d2d | 105 | |
altb2 | 0:a201a6cd4c0c | 106 | Closed loop FRF calculus: |
altb2 | 0:a201a6cd4c0c | 107 | S = 1 - T; |
altb2 | 0:a201a6cd4c0c | 108 | PS = P*S; |
altb2 | 0:a201a6cd4c0c | 109 | CS = T/P; |
altb2 | 0:a201a6cd4c0c | 110 | C = C/S; |
altb2 | 0:a201a6cd4c0c | 111 | |
altb2 | 0:a201a6cd4c0c | 112 | Excitation at excitation input (2): |
altb2 | 1:b54eb3e24d2d | 113 | |
altb2 | 0:a201a6cd4c0c | 114 | - Measuring the plant P = Gyu and the closed loop tf PS = P/(1 + PC) = Gyr: |
altb2 | 1:b54eb3e24d2d | 115 | |
altb2 | 0:a201a6cd4c0c | 116 | u = C(w - y) + exc; |
altb2 | 0:a201a6cd4c0c | 117 | ... write output u here! it follows exc(k+1) ... |
altb2 | 0:a201a6cd4c0c | 118 | exc = Wobble(u, y); |
altb2 | 1:b54eb3e24d2d | 119 | |
altb2 | 0:a201a6cd4c0c | 120 | Closed loop FRF calculus: |
altb2 | 0:a201a6cd4c0c | 121 | S = PS/P; |
altb2 | 0:a201a6cd4c0c | 122 | T = 1 - S; |
altb2 | 0:a201a6cd4c0c | 123 | CS = T/P; |
altb2 | 0:a201a6cd4c0c | 124 | C = C/S; |
altb2 | 0:a201a6cd4c0c | 125 | |
altb2 | 0:a201a6cd4c0c | 126 | |
altb2 | 0:a201a6cd4c0c | 127 | Usage: |
altb2 | 1:b54eb3e24d2d | 128 | exc(k+1) = myGPA(inp(k), out(k)) does update the internal states of the |
altb2 | 0:a201a6cd4c0c | 129 | gpa at the timestep k and returns the excitation signal for the timestep |
altb2 | 1:b54eb3e24d2d | 130 | k+1. The FRF data are plotted to a terminal (Putty) over a serial |
altb2 | 0:a201a6cd4c0c | 131 | connection and look as follows: |
altb2 | 1:b54eb3e24d2d | 132 | |
altb2 | 0:a201a6cd4c0c | 133 | -------------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 134 | fexc[Hz] |Gyu| deg(Gyu) |Gyr| deg(Gyr) |U| |Y| |R| |
altb2 | 0:a201a6cd4c0c | 135 | -------------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 136 | 5.0000e-02 1.001e+00 -0.309 1.001e+00 -0.309 4.000e-01 4.000e-01 4.005e-01 |
altb2 | 0:a201a6cd4c0c | 137 | . . . . . . . . |
altb2 | 0:a201a6cd4c0c | 138 | . . . . . . . . |
altb2 | 0:a201a6cd4c0c | 139 | . . . . . . . . |
altb2 | 1:b54eb3e24d2d | 140 | |
altb2 | 0:a201a6cd4c0c | 141 | In Matlab you can use the editor as follows: |
altb2 | 0:a201a6cd4c0c | 142 | data = [... insert measurement data here ...]; |
altb2 | 0:a201a6cd4c0c | 143 | gyu = frd(data(:,2).*exp(1i*data(:,3)*pi/180), data(:,1), Ts, 'Units', 'Hz'); |
altb2 | 0:a201a6cd4c0c | 144 | gyr = frd(data(:,4).*exp(1i*data(:,5)*pi/180), data(:,1), Ts, 'Units', 'Hz'); |
altb2 | 0:a201a6cd4c0c | 145 | |
altb2 | 0:a201a6cd4c0c | 146 | If you're evaluating more than one measurement which contain equal frequency points use: |
altb2 | 0:a201a6cd4c0c | 147 | data = [data1; data2]; |
altb2 | 0:a201a6cd4c0c | 148 | [~, ind] = unique(data(:,1), 'stable'); |
altb2 | 0:a201a6cd4c0c | 149 | data = data(ind,:); |
altb2 | 0:a201a6cd4c0c | 150 | |
altb2 | 0:a201a6cd4c0c | 151 | |
altb2 | 1:b54eb3e24d2d | 152 | Autor and Copyrigth: 2018 / 2019 / 2020 / M.E. Peter |
altb2 | 1:b54eb3e24d2d | 153 | |
altb2 | 0:a201a6cd4c0c | 154 | */ |
altb2 | 0:a201a6cd4c0c | 155 | |
altb2 | 0:a201a6cd4c0c | 156 | #include "GPA.h" |
altb2 | 0:a201a6cd4c0c | 157 | #include "mbed.h" |
altb2 | 0:a201a6cd4c0c | 158 | #include "math.h" |
altb2 | 1:b54eb3e24d2d | 159 | #define pi 3.14159265358979323846 // M_PI |
altb2 | 0:a201a6cd4c0c | 160 | |
altb2 | 0:a201a6cd4c0c | 161 | using namespace std; |
altb2 | 0:a201a6cd4c0c | 162 | |
altb2 | 0:a201a6cd4c0c | 163 | // ----------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 164 | // instantiate |
altb2 | 0:a201a6cd4c0c | 165 | // ----------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 166 | |
altb2 | 0:a201a6cd4c0c | 167 | GPA::GPA(float fMin, float fMax, int NfexcDes, float Aexc0, float Aexc1, float Ts) |
altb2 | 0:a201a6cd4c0c | 168 | { |
altb2 | 1:b54eb3e24d2d | 169 | doPrint = true; |
altb2 | 0:a201a6cd4c0c | 170 | int NperMin = 3; |
altb2 | 0:a201a6cd4c0c | 171 | int NmeasMin = (int)ceil(1.0f/Ts); |
altb2 | 1:b54eb3e24d2d | 172 | int Nstart = (int)ceil(3.0f/Ts); |
altb2 | 1:b54eb3e24d2d | 173 | int Nsweep = (int)ceil(0.0f/Ts); |
altb2 | 0:a201a6cd4c0c | 174 | |
altb2 | 1:b54eb3e24d2d | 175 | setParameters(fMin, fMax, NfexcDes, NperMin, NmeasMin, Ts, Aexc0, Aexc1, Nstart, Nsweep, doPrint); |
altb2 | 1:b54eb3e24d2d | 176 | } |
altb2 | 0:a201a6cd4c0c | 177 | |
altb2 | 1:b54eb3e24d2d | 178 | GPA::GPA(float fMin, float fMax, int NfexcDes, int NperMin, int NmeasMin, float Ts, float Aexc0, float Aexc1, int Nstart, int Nsweep) |
altb2 | 1:b54eb3e24d2d | 179 | { |
altb2 | 1:b54eb3e24d2d | 180 | doPrint = true; |
altb2 | 1:b54eb3e24d2d | 181 | setParameters(fMin, fMax, NfexcDes, NperMin, NmeasMin, Ts, Aexc0, Aexc1, Nstart, Nsweep, doPrint); |
altb2 | 0:a201a6cd4c0c | 182 | } |
altb2 | 0:a201a6cd4c0c | 183 | |
altb2 | 1:b54eb3e24d2d | 184 | GPA::GPA(float f0, float f1, float *fexcDes, int NfexcDes, int NperMin, int NmeasMin, float Ts, float Aexc0, float Aexc1, int Nstart, int Nsweep) |
altb2 | 0:a201a6cd4c0c | 185 | { |
altb2 | 1:b54eb3e24d2d | 186 | doPrint = true; |
altb2 | 1:b54eb3e24d2d | 187 | assignParameters(NfexcDes, NperMin, NmeasMin, Ts, Nstart, Nsweep); |
altb2 | 0:a201a6cd4c0c | 188 | |
altb2 | 1:b54eb3e24d2d | 189 | // convert fexcDes from float to float, it is assumed that it is sorted |
altb2 | 1:b54eb3e24d2d | 190 | this->fexcDes = (float*)malloc(NfexcDes*sizeof(float)); |
altb2 | 1:b54eb3e24d2d | 191 | for(int i = 0; i < NfexcDes; i++) { |
altb2 | 1:b54eb3e24d2d | 192 | this->fexcDes[i] = (float)fexcDes[i]; |
altb2 | 1:b54eb3e24d2d | 193 | } |
altb2 | 0:a201a6cd4c0c | 194 | |
altb2 | 1:b54eb3e24d2d | 195 | calculateDecreasingAmplitudeCoefficients(Aexc0, Aexc1); |
altb2 | 1:b54eb3e24d2d | 196 | initializeConstants(Ts); |
altb2 | 0:a201a6cd4c0c | 197 | assignFilterStorage(); |
altb2 | 0:a201a6cd4c0c | 198 | reset(); |
altb2 | 0:a201a6cd4c0c | 199 | } |
altb2 | 0:a201a6cd4c0c | 200 | |
altb2 | 1:b54eb3e24d2d | 201 | GPA::GPA(float *fexcDes, int NfexcDes, int NperMin, int NmeasMin, float Ts, float Aexc0, float Aexc1, int Nstart, int Nsweep) |
altb2 | 0:a201a6cd4c0c | 202 | { |
altb2 | 1:b54eb3e24d2d | 203 | doPrint = true; |
altb2 | 1:b54eb3e24d2d | 204 | assignParameters(NfexcDes, NperMin, NmeasMin, Ts, Nstart, Nsweep); |
altb2 | 1:b54eb3e24d2d | 205 | |
altb2 | 1:b54eb3e24d2d | 206 | // convert fexcDes from float to float, it is assumed that it is sorted |
altb2 | 1:b54eb3e24d2d | 207 | this->fexcDes = (float*)malloc(NfexcDes*sizeof(float)); |
altb2 | 0:a201a6cd4c0c | 208 | for(int i = 0; i < NfexcDes; i++) { |
altb2 | 1:b54eb3e24d2d | 209 | this->fexcDes[i] = fexcDes[i]; |
altb2 | 0:a201a6cd4c0c | 210 | } |
altb2 | 1:b54eb3e24d2d | 211 | |
altb2 | 1:b54eb3e24d2d | 212 | calculateDecreasingAmplitudeCoefficients(Aexc0, Aexc1); |
altb2 | 1:b54eb3e24d2d | 213 | initializeConstants(Ts); |
altb2 | 0:a201a6cd4c0c | 214 | assignFilterStorage(); |
altb2 | 0:a201a6cd4c0c | 215 | reset(); |
altb2 | 0:a201a6cd4c0c | 216 | } |
altb2 | 0:a201a6cd4c0c | 217 | |
altb2 | 1:b54eb3e24d2d | 218 | GPA::GPA(float fMin, float fMax, int NfexcDes, int NperMin, int NmeasMin, float Ts, float Aexc0, float Aexc1, int Nstart, int Nsweep, bool doPrint) |
altb2 | 0:a201a6cd4c0c | 219 | { |
altb2 | 1:b54eb3e24d2d | 220 | setParameters(fMin, fMax, NfexcDes, NperMin, NmeasMin, Ts, Aexc0, Aexc1, Nstart, Nsweep, doPrint); |
altb2 | 0:a201a6cd4c0c | 221 | } |
altb2 | 0:a201a6cd4c0c | 222 | |
altb2 | 0:a201a6cd4c0c | 223 | // ----------------------------------------------------------------------------- |
altb2 | 1:b54eb3e24d2d | 224 | // virtual, reset and set |
altb2 | 0:a201a6cd4c0c | 225 | // ----------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 226 | |
altb2 | 0:a201a6cd4c0c | 227 | GPA::~GPA() {} |
altb2 | 0:a201a6cd4c0c | 228 | |
altb2 | 1:b54eb3e24d2d | 229 | void GPA::setParameters(float fMin, float fMax, int NfexcDes, int NperMin, int NmeasMin, float Ts, float Aexc0, float Aexc1, int Nstart, int Nsweep, bool doPrint) |
altb2 | 1:b54eb3e24d2d | 230 | { |
altb2 | 1:b54eb3e24d2d | 231 | this->doPrint = doPrint; |
altb2 | 1:b54eb3e24d2d | 232 | assignParameters(NfexcDes, NperMin, NmeasMin, Ts, Nstart, Nsweep); |
altb2 | 1:b54eb3e24d2d | 233 | |
altb2 | 1:b54eb3e24d2d | 234 | // calculate logarithmic spaced frequency points |
altb2 | 1:b54eb3e24d2d | 235 | fexcDes = (float*)malloc(NfexcDes*sizeof(float)); |
altb2 | 1:b54eb3e24d2d | 236 | fexcDesLogspace(fMin, fMax, NfexcDes); |
altb2 | 1:b54eb3e24d2d | 237 | |
altb2 | 1:b54eb3e24d2d | 238 | calculateDecreasingAmplitudeCoefficients(Aexc0, Aexc1); |
altb2 | 1:b54eb3e24d2d | 239 | initializeConstants(Ts); |
altb2 | 1:b54eb3e24d2d | 240 | assignFilterStorage(); |
altb2 | 1:b54eb3e24d2d | 241 | reset(); |
altb2 | 1:b54eb3e24d2d | 242 | |
altb2 | 1:b54eb3e24d2d | 243 | } |
altb2 | 1:b54eb3e24d2d | 244 | |
altb2 | 0:a201a6cd4c0c | 245 | void GPA::reset() |
altb2 | 0:a201a6cd4c0c | 246 | { |
altb2 | 0:a201a6cd4c0c | 247 | Nmeas = 0; |
altb2 | 0:a201a6cd4c0c | 248 | Nper = 0; |
altb2 | 0:a201a6cd4c0c | 249 | dfexc = 0.0; |
altb2 | 0:a201a6cd4c0c | 250 | fexc = 0.0; |
altb2 | 1:b54eb3e24d2d | 251 | fexcPast = 0.0f; |
altb2 | 1:b54eb3e24d2d | 252 | dfexcj = 0.0f; |
altb2 | 0:a201a6cd4c0c | 253 | i = 1; // iterating through desired frequency points |
altb2 | 0:a201a6cd4c0c | 254 | j = 1; // iterating through measurement points w.r.t. reachable frequency |
altb2 | 0:a201a6cd4c0c | 255 | scaleG = 0.0; |
altb2 | 0:a201a6cd4c0c | 256 | cr = 0.0; |
altb2 | 0:a201a6cd4c0c | 257 | ci = 0.0; |
altb2 | 0:a201a6cd4c0c | 258 | for(int i = 0; i < 3; i++) { |
altb2 | 0:a201a6cd4c0c | 259 | sU[i] = 0.0; |
altb2 | 0:a201a6cd4c0c | 260 | sY[i] = 0.0; |
altb2 | 0:a201a6cd4c0c | 261 | } |
altb2 | 0:a201a6cd4c0c | 262 | sinarg = 0.0; |
altb2 | 1:b54eb3e24d2d | 263 | sinargR = 0.0f; |
altb2 | 0:a201a6cd4c0c | 264 | NmeasTotal = 0; |
altb2 | 1:b54eb3e24d2d | 265 | Aexc = 0.0f; |
altb2 | 0:a201a6cd4c0c | 266 | pi2Tsfexc = 0.0; |
altb2 | 1:b54eb3e24d2d | 267 | Nsweep_i = Nstart; |
altb2 | 1:b54eb3e24d2d | 268 | AexcOut = 0.0f; |
altb2 | 1:b54eb3e24d2d | 269 | gpaData.fexc = 0.0f; |
altb2 | 1:b54eb3e24d2d | 270 | gpaData.absGyu = 0.0f; |
altb2 | 1:b54eb3e24d2d | 271 | gpaData.angGyu = 0.0f; |
altb2 | 1:b54eb3e24d2d | 272 | gpaData.absGyr = 0.0f; |
altb2 | 1:b54eb3e24d2d | 273 | gpaData.angGyr = 0.0f; |
altb2 | 1:b54eb3e24d2d | 274 | gpaData.Umag = 0.0f; |
altb2 | 1:b54eb3e24d2d | 275 | gpaData.Ymag = 0.0f; |
altb2 | 1:b54eb3e24d2d | 276 | gpaData.Rmag = 0.0f; |
altb2 | 1:b54eb3e24d2d | 277 | gpaData.MeasPointFinished = false; |
altb2 | 1:b54eb3e24d2d | 278 | gpaData.MeasFinished = false; |
altb2 | 1:b54eb3e24d2d | 279 | gpaData.ind = -1; |
altb2 | 1:b54eb3e24d2d | 280 | |
altb2 | 0:a201a6cd4c0c | 281 | } |
altb2 | 0:a201a6cd4c0c | 282 | |
altb2 | 0:a201a6cd4c0c | 283 | // ----------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 284 | // update (operator) |
altb2 | 1:b54eb3e24d2d | 285 | // ----------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 286 | |
altb2 | 1:b54eb3e24d2d | 287 | float GPA::update(float inp, float out) |
altb2 | 0:a201a6cd4c0c | 288 | { |
altb2 | 0:a201a6cd4c0c | 289 | // a new frequency point has been reached |
altb2 | 0:a201a6cd4c0c | 290 | if(j == 1) { |
altb2 | 0:a201a6cd4c0c | 291 | // user info |
altb2 | 1:b54eb3e24d2d | 292 | if(i == 1 && doPrint) { |
altb2 | 0:a201a6cd4c0c | 293 | printLine(); |
altb2 | 0:a201a6cd4c0c | 294 | printf(" fexc[Hz] |Gyu| deg(Gyu) |Gyr| deg(Gyr) |U| |Y| |R|\r\n"); |
altb2 | 0:a201a6cd4c0c | 295 | printLine(); |
altb2 | 0:a201a6cd4c0c | 296 | } |
altb2 | 0:a201a6cd4c0c | 297 | // get a new unique frequency point |
altb2 | 0:a201a6cd4c0c | 298 | while(fexc == fexcPast) { |
altb2 | 0:a201a6cd4c0c | 299 | // measurement finished |
altb2 | 0:a201a6cd4c0c | 300 | if(i > NfexcDes) { |
altb2 | 1:b54eb3e24d2d | 301 | gpaData.MeasPointFinished = false; |
altb2 | 1:b54eb3e24d2d | 302 | gpaData.MeasFinished = true; |
altb2 | 0:a201a6cd4c0c | 303 | return 0.0f; |
altb2 | 0:a201a6cd4c0c | 304 | } |
altb2 | 0:a201a6cd4c0c | 305 | calcGPAmeasPara(fexcDes[i - 1]); |
altb2 | 0:a201a6cd4c0c | 306 | // secure fexc is not higher or equal to nyquist frequency |
altb2 | 0:a201a6cd4c0c | 307 | if(fexc >= fnyq) { |
altb2 | 0:a201a6cd4c0c | 308 | fexc = fexcPast; |
altb2 | 0:a201a6cd4c0c | 309 | } |
altb2 | 0:a201a6cd4c0c | 310 | // no frequency found |
altb2 | 0:a201a6cd4c0c | 311 | if(fexc == fexcPast) { |
altb2 | 0:a201a6cd4c0c | 312 | i += 1; |
altb2 | 0:a201a6cd4c0c | 313 | } else { |
altb2 | 0:a201a6cd4c0c | 314 | Aexc = aAexcDes/fexc + bAexcDes; |
altb2 | 0:a201a6cd4c0c | 315 | pi2Tsfexc = pi2Ts*fexc; |
altb2 | 0:a201a6cd4c0c | 316 | } |
altb2 | 0:a201a6cd4c0c | 317 | } |
altb2 | 0:a201a6cd4c0c | 318 | // filter scaling |
altb2 | 0:a201a6cd4c0c | 319 | scaleG = 1.0/sqrt((double)Nmeas); |
altb2 | 0:a201a6cd4c0c | 320 | // filter coefficients |
altb2 | 0:a201a6cd4c0c | 321 | cr = cos(pi2Tsfexc); |
altb2 | 0:a201a6cd4c0c | 322 | ci = sin(pi2Tsfexc); |
altb2 | 0:a201a6cd4c0c | 323 | // set filter storage zero |
altb2 | 0:a201a6cd4c0c | 324 | for(int i = 0; i < 3; i++) { |
altb2 | 0:a201a6cd4c0c | 325 | sU[i] = 0.0; |
altb2 | 0:a201a6cd4c0c | 326 | sY[i] = 0.0; |
altb2 | 0:a201a6cd4c0c | 327 | } |
altb2 | 1:b54eb3e24d2d | 328 | gpaData.MeasPointFinished = false; |
altb2 | 0:a201a6cd4c0c | 329 | } |
altb2 | 0:a201a6cd4c0c | 330 | // perfomre the sweep or measure |
altb2 | 1:b54eb3e24d2d | 331 | if(j <= Nsweep_i) { |
altb2 | 1:b54eb3e24d2d | 332 | dfexcj = ((float)j - 1.0f)/((float)Nsweep_i - 1.0f); |
altb2 | 1:b54eb3e24d2d | 333 | dfexcj = div12pi*sinf(pi4*dfexcj) - div812pi*sinf((float)pi2*dfexcj) + dfexcj; |
altb2 | 1:b54eb3e24d2d | 334 | dfexc = fexcPast + (fexc - fexcPast)*dfexcj; |
altb2 | 1:b54eb3e24d2d | 335 | AexcOut = AexcPast + (Aexc - AexcPast)*dfexcj; |
altb2 | 0:a201a6cd4c0c | 336 | } else { |
altb2 | 0:a201a6cd4c0c | 337 | dfexc = fexc; |
altb2 | 0:a201a6cd4c0c | 338 | AexcOut = Aexc; |
altb2 | 0:a201a6cd4c0c | 339 | // one point DFT filter step for signal su |
altb2 | 0:a201a6cd4c0c | 340 | sU[0] = scaleG*inp + 2.0*cr*sU[1] - sU[2]; |
altb2 | 0:a201a6cd4c0c | 341 | sU[2] = sU[1]; |
altb2 | 0:a201a6cd4c0c | 342 | sU[1] = sU[0]; |
altb2 | 0:a201a6cd4c0c | 343 | // one point DFT filter step for signal sy |
altb2 | 0:a201a6cd4c0c | 344 | sY[0] = scaleG*out + 2.0*cr*sY[1] - sY[2]; |
altb2 | 0:a201a6cd4c0c | 345 | sY[2] = sY[1]; |
altb2 | 0:a201a6cd4c0c | 346 | sY[1] = sY[0]; |
altb2 | 0:a201a6cd4c0c | 347 | } |
altb2 | 1:b54eb3e24d2d | 348 | // copy starting value for ang(R) |
altb2 | 1:b54eb3e24d2d | 349 | if(j == 1 || j == Nsweep_i + 1) sinargR = sinarg; |
altb2 | 0:a201a6cd4c0c | 350 | // measurement of frequencypoint is finished |
altb2 | 1:b54eb3e24d2d | 351 | if(j == Nmeas + Nsweep_i) { |
altb2 | 0:a201a6cd4c0c | 352 | fexcPast = fexc; |
altb2 | 0:a201a6cd4c0c | 353 | AexcPast = Aexc; |
altb2 | 1:b54eb3e24d2d | 354 | Nsweep_i = Nsweep; |
altb2 | 0:a201a6cd4c0c | 355 | // calculate the one point dft |
altb2 | 1:b54eb3e24d2d | 356 | float Ureal = (float)(2.0*scaleG*(cr*sU[1] - sU[2])); |
altb2 | 1:b54eb3e24d2d | 357 | float Uimag = (float)(2.0*scaleG*ci*sU[1]); |
altb2 | 1:b54eb3e24d2d | 358 | float Yreal = (float)(2.0*scaleG*(cr*sY[1] - sY[2])); |
altb2 | 1:b54eb3e24d2d | 359 | float Yimag = (float)(2.0*scaleG*ci*sY[1]); |
altb2 | 0:a201a6cd4c0c | 360 | // calculate magnitude and angle |
altb2 | 1:b54eb3e24d2d | 361 | float Umag = sqrtf(Ureal*Ureal + Uimag*Uimag); |
altb2 | 1:b54eb3e24d2d | 362 | float Ymag = sqrtf(Yreal*Yreal + Yimag*Yimag); |
altb2 | 1:b54eb3e24d2d | 363 | gpaData.fexc = (float)fexc; |
altb2 | 1:b54eb3e24d2d | 364 | gpaData.absGyu = Ymag/Umag; |
altb2 | 1:b54eb3e24d2d | 365 | gpaData.angGyu = wrapAngle(atan2f(Yimag, Yreal) - atan2f(Uimag, Ureal))*rad2deg; |
altb2 | 1:b54eb3e24d2d | 366 | gpaData.absGyr = Ymag/Aexc; |
altb2 | 1:b54eb3e24d2d | 367 | gpaData.angGyr = wrapAngle(atan2f(Yimag, Yreal) + fmod(piDiv2 - sinargR, (float)pi2))*rad2deg; |
altb2 | 1:b54eb3e24d2d | 368 | gpaData.Umag = Umag; |
altb2 | 1:b54eb3e24d2d | 369 | gpaData.Ymag = Ymag; |
altb2 | 1:b54eb3e24d2d | 370 | gpaData.Rmag = Aexc; |
altb2 | 1:b54eb3e24d2d | 371 | gpaData.MeasPointFinished = true; |
altb2 | 1:b54eb3e24d2d | 372 | gpaData.ind++; |
altb2 | 0:a201a6cd4c0c | 373 | // user info |
altb2 | 1:b54eb3e24d2d | 374 | if(doPrint) { |
altb2 | 1:b54eb3e24d2d | 375 | printf("%11.4e %9.3e %8.3f %9.3e %8.3f %9.3e %9.3e %9.3e\r\n", gpaData.fexc, gpaData.absGyu, gpaData.angGyu, gpaData.absGyr, gpaData.angGyr, gpaData.Umag, gpaData.Ymag, gpaData.Rmag); |
altb2 | 1:b54eb3e24d2d | 376 | } |
altb2 | 0:a201a6cd4c0c | 377 | i += 1; |
altb2 | 0:a201a6cd4c0c | 378 | j = 1; |
altb2 | 0:a201a6cd4c0c | 379 | } else { |
altb2 | 0:a201a6cd4c0c | 380 | j += 1; |
altb2 | 0:a201a6cd4c0c | 381 | } |
altb2 | 0:a201a6cd4c0c | 382 | // calculate the excitation |
altb2 | 0:a201a6cd4c0c | 383 | sinarg = fmod(sinarg + pi2Ts*dfexc, pi2); |
altb2 | 0:a201a6cd4c0c | 384 | NmeasTotal += 1; |
altb2 | 1:b54eb3e24d2d | 385 | return AexcOut*sinf(sinarg); |
altb2 | 0:a201a6cd4c0c | 386 | } |
altb2 | 0:a201a6cd4c0c | 387 | |
altb2 | 0:a201a6cd4c0c | 388 | // ----------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 389 | // private functions |
altb2 | 1:b54eb3e24d2d | 390 | // ----------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 391 | |
altb2 | 1:b54eb3e24d2d | 392 | void GPA::assignParameters(int NfexcDes, int NperMin, int NmeasMin, float Ts, int Nstart, int Nsweep) |
altb2 | 0:a201a6cd4c0c | 393 | { |
altb2 | 0:a201a6cd4c0c | 394 | this->NfexcDes = NfexcDes; |
altb2 | 0:a201a6cd4c0c | 395 | this->NperMin = NperMin; |
altb2 | 0:a201a6cd4c0c | 396 | this->NmeasMin = NmeasMin; |
altb2 | 0:a201a6cd4c0c | 397 | this->Ts = Ts; |
altb2 | 1:b54eb3e24d2d | 398 | this->Nstart = Nstart; |
altb2 | 1:b54eb3e24d2d | 399 | this->Nsweep = Nsweep; |
altb2 | 0:a201a6cd4c0c | 400 | } |
altb2 | 0:a201a6cd4c0c | 401 | |
altb2 | 1:b54eb3e24d2d | 402 | void GPA::calculateDecreasingAmplitudeCoefficients(float Aexc0, float Aexc1) |
altb2 | 0:a201a6cd4c0c | 403 | { |
altb2 | 0:a201a6cd4c0c | 404 | // calculate coefficients for decreasing amplitude (1/fexc) |
altb2 | 1:b54eb3e24d2d | 405 | this->aAexcDes = (Aexc1 - Aexc0)/(1.0f/fexcDes[NfexcDes-1] - 1.0f/fexcDes[0]); |
altb2 | 1:b54eb3e24d2d | 406 | this->bAexcDes = Aexc0 - aAexcDes/fexcDes[0]; |
altb2 | 0:a201a6cd4c0c | 407 | } |
altb2 | 0:a201a6cd4c0c | 408 | |
altb2 | 1:b54eb3e24d2d | 409 | void GPA::initializeConstants(float Ts) |
altb2 | 0:a201a6cd4c0c | 410 | { |
altb2 | 1:b54eb3e24d2d | 411 | fnyq = 1.0f/2.0f/Ts; |
altb2 | 0:a201a6cd4c0c | 412 | pi2 = 2.0*pi; |
altb2 | 1:b54eb3e24d2d | 413 | pi4 = 4.0f*(float)pi; |
altb2 | 1:b54eb3e24d2d | 414 | pi2Ts = 2.0*pi*(double)Ts;// 2.0*pi*Ts; |
altb2 | 1:b54eb3e24d2d | 415 | piDiv2 = (float)pi/2.0f; |
altb2 | 0:a201a6cd4c0c | 416 | rad2deg = 180.0f/(float)pi; |
altb2 | 1:b54eb3e24d2d | 417 | div12pi = 1.0f/(12.0f*(float)pi); |
altb2 | 1:b54eb3e24d2d | 418 | div812pi = 8.0f/(12.0f*(float)pi); |
altb2 | 0:a201a6cd4c0c | 419 | } |
altb2 | 0:a201a6cd4c0c | 420 | |
altb2 | 0:a201a6cd4c0c | 421 | void GPA::assignFilterStorage() |
altb2 | 0:a201a6cd4c0c | 422 | { |
altb2 | 0:a201a6cd4c0c | 423 | sU = (double*)malloc(3*sizeof(double)); |
altb2 | 1:b54eb3e24d2d | 424 | sY = (double*)malloc(3*sizeof(double)); |
altb2 | 0:a201a6cd4c0c | 425 | } |
altb2 | 0:a201a6cd4c0c | 426 | |
altb2 | 1:b54eb3e24d2d | 427 | void GPA::fexcDesLogspace(float fMin, float fMax, int NfexcDes) |
altb2 | 0:a201a6cd4c0c | 428 | { |
altb2 | 0:a201a6cd4c0c | 429 | // calculate logarithmic spaced frequency points |
altb2 | 1:b54eb3e24d2d | 430 | float Gain = log10f(fMax/fMin)/((float)NfexcDes - 1.0f); |
altb2 | 1:b54eb3e24d2d | 431 | float expon = 0.0; |
altb2 | 0:a201a6cd4c0c | 432 | for(int i = 0; i < NfexcDes; i++) { |
altb2 | 1:b54eb3e24d2d | 433 | fexcDes[i] = fMin*powf(10.0f, expon); |
altb2 | 0:a201a6cd4c0c | 434 | expon += Gain; |
altb2 | 0:a201a6cd4c0c | 435 | } |
altb2 | 0:a201a6cd4c0c | 436 | } |
altb2 | 0:a201a6cd4c0c | 437 | |
altb2 | 1:b54eb3e24d2d | 438 | void GPA::calcGPAmeasPara(float fexcDes_i) |
altb2 | 0:a201a6cd4c0c | 439 | { |
altb2 | 0:a201a6cd4c0c | 440 | // Nmeas has to be an integer |
altb2 | 0:a201a6cd4c0c | 441 | Nper = NperMin; |
altb2 | 1:b54eb3e24d2d | 442 | Nmeas = (int)floor((float)Nper/fexcDes_i/Ts + 0.5f); |
altb2 | 0:a201a6cd4c0c | 443 | // secure that the minimal number of measurements is fullfilled |
altb2 | 0:a201a6cd4c0c | 444 | int Ndelta = NmeasMin - Nmeas; |
altb2 | 0:a201a6cd4c0c | 445 | if(Ndelta > 0) { |
altb2 | 1:b54eb3e24d2d | 446 | Nper = (int)ceil((float)NmeasMin*fexcDes_i*Ts); |
altb2 | 1:b54eb3e24d2d | 447 | Nmeas = (int)floor((float)Nper/fexcDes_i/Ts + 0.5f); |
altb2 | 0:a201a6cd4c0c | 448 | } |
altb2 | 0:a201a6cd4c0c | 449 | // evaluating reachable frequency |
altb2 | 1:b54eb3e24d2d | 450 | fexc = (float)((double)Nper/(double)Nmeas/(double)Ts); |
altb2 | 0:a201a6cd4c0c | 451 | } |
altb2 | 0:a201a6cd4c0c | 452 | |
altb2 | 1:b54eb3e24d2d | 453 | float GPA::wrapAngle(float angle) |
altb2 | 0:a201a6cd4c0c | 454 | { |
altb2 | 0:a201a6cd4c0c | 455 | // wrap angle from (-2pi,2pi) into (-pi,pi) |
altb2 | 1:b54eb3e24d2d | 456 | if(abs(angle) > (float)pi) angle -= copysignf(-(float)pi2, angle); // -1*sign(angle)*2*pi + angle; |
altb2 | 0:a201a6cd4c0c | 457 | return angle; |
altb2 | 0:a201a6cd4c0c | 458 | } |
altb2 | 0:a201a6cd4c0c | 459 | |
altb2 | 0:a201a6cd4c0c | 460 | void GPA::printLongLine() |
altb2 | 0:a201a6cd4c0c | 461 | { |
altb2 | 1:b54eb3e24d2d | 462 | printf("-------------------------------------------------------------------------------------------------------------------------------\r\n"); |
altb2 | 0:a201a6cd4c0c | 463 | } |
altb2 | 0:a201a6cd4c0c | 464 | |
altb2 | 0:a201a6cd4c0c | 465 | // ----------------------------------------------------------------------------- |
altb2 | 1:b54eb3e24d2d | 466 | // public functions (mainly for debugging) |
altb2 | 1:b54eb3e24d2d | 467 | // ----------------------------------------------------------------------------- |
altb2 | 0:a201a6cd4c0c | 468 | |
altb2 | 0:a201a6cd4c0c | 469 | void GPA::printGPAfexcDes() |
altb2 | 0:a201a6cd4c0c | 470 | { |
altb2 | 0:a201a6cd4c0c | 471 | printLine(); |
altb2 | 0:a201a6cd4c0c | 472 | for(int i = 0; i < NfexcDes; i++) { |
altb2 | 1:b54eb3e24d2d | 473 | printf("%9.4f\r\n", fexcDes[i]); |
altb2 | 0:a201a6cd4c0c | 474 | } |
altb2 | 0:a201a6cd4c0c | 475 | } |
altb2 | 0:a201a6cd4c0c | 476 | |
altb2 | 0:a201a6cd4c0c | 477 | void GPA::printGPAmeasPara() |
altb2 | 0:a201a6cd4c0c | 478 | { |
altb2 | 0:a201a6cd4c0c | 479 | printLine(); |
altb2 | 1:b54eb3e24d2d | 480 | printf(" fexcDes[Hz] fexc[Hz] Aexc Nmeas Nper Nsweep_i\r\n"); |
altb2 | 0:a201a6cd4c0c | 481 | printLine(); |
altb2 | 0:a201a6cd4c0c | 482 | for(int i = 0; i < NfexcDes; i++) { |
altb2 | 0:a201a6cd4c0c | 483 | calcGPAmeasPara(fexcDes[i]); |
altb2 | 0:a201a6cd4c0c | 484 | if(fexc == fexcPast || fexc >= fnyq) { |
altb2 | 0:a201a6cd4c0c | 485 | fexc = 0.0; |
altb2 | 1:b54eb3e24d2d | 486 | Aexc = 0.0f; |
altb2 | 0:a201a6cd4c0c | 487 | Nmeas = 0; |
altb2 | 0:a201a6cd4c0c | 488 | Nper = 0; |
altb2 | 1:b54eb3e24d2d | 489 | Nsweep_i = 0; |
altb2 | 0:a201a6cd4c0c | 490 | } else { |
altb2 | 0:a201a6cd4c0c | 491 | Aexc = aAexcDes/fexc + bAexcDes; |
altb2 | 0:a201a6cd4c0c | 492 | fexcPast = fexc; |
altb2 | 0:a201a6cd4c0c | 493 | AexcPast = Aexc; |
altb2 | 0:a201a6cd4c0c | 494 | } |
altb2 | 0:a201a6cd4c0c | 495 | NmeasTotal += Nmeas; |
altb2 | 1:b54eb3e24d2d | 496 | NmeasTotal += Nsweep_i; |
altb2 | 1:b54eb3e24d2d | 497 | printf("%11.4e %12.4e %10.3e %7i %6i %7i\r\n", fexcDes[i], (float)fexc, Aexc, Nmeas, Nper, Nsweep_i); |
altb2 | 1:b54eb3e24d2d | 498 | // wait(0.01); |
altb2 | 1:b54eb3e24d2d | 499 | Nsweep_i = Nsweep; |
altb2 | 0:a201a6cd4c0c | 500 | } |
altb2 | 0:a201a6cd4c0c | 501 | printGPAmeasTime(); |
altb2 | 0:a201a6cd4c0c | 502 | reset(); |
altb2 | 0:a201a6cd4c0c | 503 | } |
altb2 | 0:a201a6cd4c0c | 504 | |
altb2 | 0:a201a6cd4c0c | 505 | void GPA::printGPAmeasTime() |
altb2 | 0:a201a6cd4c0c | 506 | { |
altb2 | 0:a201a6cd4c0c | 507 | printLine(); |
altb2 | 0:a201a6cd4c0c | 508 | printf(" Number of data points : %11i\r\n", NmeasTotal); |
altb2 | 1:b54eb3e24d2d | 509 | printf(" Measurment time in sec: %12.2f\r\n", (float)NmeasTotal*Ts); |
altb2 | 0:a201a6cd4c0c | 510 | } |
altb2 | 0:a201a6cd4c0c | 511 | |
altb2 | 0:a201a6cd4c0c | 512 | void GPA::printNfexcDes() |
altb2 | 0:a201a6cd4c0c | 513 | { |
altb2 | 0:a201a6cd4c0c | 514 | printLine(); |
altb2 | 0:a201a6cd4c0c | 515 | printf(" Number of frequancy points: %3i\r\n", NfexcDes); |
altb2 | 0:a201a6cd4c0c | 516 | } |
altb2 | 0:a201a6cd4c0c | 517 | |
altb2 | 1:b54eb3e24d2d | 518 | void GPA::printLine() |
altb2 | 1:b54eb3e24d2d | 519 | { |
altb2 | 1:b54eb3e24d2d | 520 | printf("--------------------------------------------------------------------------------\r\n"); |
altb2 | 1:b54eb3e24d2d | 521 | } |
altb2 | 1:b54eb3e24d2d | 522 | |
altb2 | 1:b54eb3e24d2d | 523 | GPA::gpadata_t GPA::getGPAdata() |
altb2 | 1:b54eb3e24d2d | 524 | { |
altb2 | 1:b54eb3e24d2d | 525 | return gpaData; |
altb2 | 1:b54eb3e24d2d | 526 | } |