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measure.c
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measure.c
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/*
* Copyright (c) 2019-2024, Dmitry (DiSlord) [email protected]
* All rights reserved.
*
* This is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3, or (at your option)
* any later version.
*
* The software is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with GNU Radio; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#ifdef __VNA_MEASURE_MODULE__
// Use size optimization (module not need fast speed, better have smallest size)
#pragma GCC push_options
#pragma GCC optimize ("Os")
// Memory for measure cache data
static char measure_memory[128];
// Measure math functions
// quadratic function solver
static void match_quadratic_equation(float a, float b, float c, float *x) {
const float a_x_2 = 2.0f * a;
const float d = (b * b) - (2.0f * a_x_2 * c);
if (d < 0){
x[0] = x[1] = 0.0f;
return;
}
const float sd = vna_sqrtf(d);
x[0] = (-b + sd) / a_x_2;
x[1] = (-b - sd) / a_x_2;
}
// Search functions
// Type of get value function
typedef float (*get_value_t)(uint16_t idx);
// Search point get_value(x) = y
// Used bilinear interpolation, return value = frequency of this point
#define MEASURE_SEARCH_LEFT -1
#define MEASURE_SEARCH_RIGHT 1
static float measure_search_value(uint16_t *idx, float y, get_value_t get, int16_t mode, int16_t marker_idx) {
uint16_t x = *idx;
float y1, y2, y3;
y1 = y2 = y3 = get(x);
bool result = (y3 > y); // current position depend from start point
for(; x < sweep_points; x+=mode) {
y3 = get(x);
if(result != (y3 > y)) break;
y1 = y2;
y2 = y3;
}
if (x >= sweep_points) return 0;
x-=mode;
*idx = x;
set_marker_index(marker_idx, x);
// Now y1 > y, y2 > y, y3 <= y or y1 < y, y2 < y, y3 >= y
const float a = 0.5f * (y1 + y3) - y2;
const float b = 0.5f * (y3 - y1);
const float c = y2 - y;
float r[2];
match_quadratic_equation(a, b, c, r);
// Select result in middle 0 and 1 (in middle y2 and y3 result)
float res = (r[0] > 0 && r[0] < 1.0) ? r[0] : r[1];
// for search left need swap y1 and y3 points (use negative result)
if (mode < 0) res=-res;
return getFrequency(x) + getFrequencyStep() * res;
}
// Peak search, use bilinear interpolation for peak detect
#define MEASURE_SEARCH_MIN 0
#define MEASURE_SEARCH_MAX 1
static bool _greaterf(float x, float y) { return x > y; }
static bool _lesserf(float x, float y) { return x < y; }
static float search_peak_value(uint16_t *xp, get_value_t get, bool mode) {
bool (*compare)(float x, float y) = mode ? _greaterf : _lesserf;
uint16_t x = 0;
float y2 = get(x), ytemp;
for(int i = 1; i < sweep_points; i++) {
if(compare(ytemp = get(i), y2)) {
y2 = ytemp;
x = i;
}
}
if (x < 1 || x >= sweep_points - 1) return y2;
*xp = x;
float y1 = get(x-1);
float y3 = get(x+1);
if (y1 == y3) return y2;
// const float a = 0.5f * (y1 + y3) - y2;
// const float b = 0.5f * (y3 - y1);
// const float c = y2;
// return c - b*b/(4*a);
const float a = 8.0f * (y1 - 2.0f * y2 + y3);
const float b = y3 - y1;
const float c = y2;
return c - b * b / a;
}
static float bilinear_interpolation(float y1, float y2, float y3, float x) {
const float a = 0.5f * (y1 + y3) - y2;
const float b = 0.5f * (y3 - y1);
const float c = y2;
return a * x * x + b * x + c;
}
static bool measure_get_value(uint16_t ch, freq_t f, float *data){
if (f < frequency0 || f > frequency1)
return false;
// Search k1
uint16_t _points = sweep_points - 1;
freq_t span = frequency1 - frequency0;
uint32_t idx = (uint64_t)(f - frequency0) * (uint64_t)_points / span;
if (idx < 1 && idx > _points)
return false;
uint64_t v = (uint64_t)span * idx + _points/2;
freq_t src_f0 = frequency0 + (v ) / _points;
freq_t src_f1 = frequency0 + (v + span) / _points;
freq_t delta = src_f1 - src_f0;
float k1 = (delta == 0) ? 0.0f : (float)(f - src_f0) / delta;
#if 1
// Bilinear interpolation by k1
data[0] = bilinear_interpolation(measured[ch][idx-1][0], measured[ch][idx ][0], measured[ch][idx+1][0],k1);
data[1] = bilinear_interpolation(measured[ch][idx-1][1], measured[ch][idx ][1], measured[ch][idx+1][1],k1);
#else
// Linear Interpolate by k1
float k0 = 1.0 - k1;
data[0] = measured[ch][idx][0] * k0 + measured[ch][idx+1][0] * k1;
data[1] = measured[ch][idx][1] * k0 + measured[ch][idx+1][1] * k1;
#endif
return true;
}
//================================================================================
// Parabolic regression calculation:
// all matrix points is SUMM(x^n)
// N - points count, so SUMM(x^0) = N
// | x^0 x^1 x^2 | | a | |x^0 * y|
// | x^1 x^2 x^3 | * | b | = |x^1 * y|
// | x^2 x^3 x^4 | | c | |x^2 * y|
//
// f(x) = a + b * x + c * x * x
void parabolic_regression(int N, get_value_t getx, get_value_t gety, float *result) {
float x, y, xx, xy, xxy, xxx, xxxx, _x, _y, _xx, _xy;
x = y = xx = xy = xxy = xxx = xxxx = 0.0f;
for (int i = 0; i < N; ++i) {
_x = getx(i); _y = gety(i); // Get x and y
_xx = _x*_x; _xy = _x*_y;
x += _x; y += _y; // SUMM(x^1) and SUMM(x^0 * y)
xx += _xx; xy += _xy; // SUMM(x^2) and SUMM(x^1 * y)
xxx += _x*_xx; xxy += _x*_xy; // SUMM(x^3) and SUMM(x^2 * y)
xxxx+= _xx*_xx; // SUMM(x^4)
}
float xm = x / N, ym = y / N, xxm = xx / N, a, b, c;
xxxx-= xx*xxm;
xxx -= xx* xm; xxy -= xx* ym;
xx -= x* xm; xy -= x* ym;
c = (xx *xxy - xxx* xy) / (xxxx*xx - xxx*xxx);
b = (xxxx* xy - xxx*xxy) / (xxxx*xx - xxx*xxx);
a = ym - b*xm - c*xxm;
result[0] = a;
result[1] = b;
result[2] = c;
}
//================================================================================
// Linear regression calculation
// all matrix points is SUMM(x^n)
// N - points count, so SUMM(x^0) = N
// | x^0 x^1 | | a | |x^0 * y|
// | x^1 x^2 | * | b | = |x^1 * y|
//
// f(x) = a + b * x
void linear_regression(int N, get_value_t getx, get_value_t gety, float *result) {
float x, y, xx, xy, _x, _y, _xx, _xy;
x = y = xx = xy = 0.0f;
for (int i = 0; i < N; ++i) {
_x = getx(i); _y = gety(i); // Get x and y
_xx = _x*_x; _xy = _x*_y;
x += _x; y += _y; // SUMM(x^1) and SUMM(x^0 * y)
xx += _xx; xy += _xy; // SUMM(x^2) and SUMM(x^1 * y)
}
float xm = x / N, ym = y / N, a, b;
b = (xy - x * ym) / (xx - x * xm);
a = ym - b * xm;
result[0] = a;
result[1] = b;
}
#ifdef __USE_LC_MATCHING__
// calculate physical component values to match an impendace to 'ref_impedance' (ie 50R)
typedef struct
{
float xps; // Reactance parallel to source (can be NAN if not applicable)
float xs; // Serial reactance (can be 0.0 if not applicable)
float xpl; // Reactance parallel to load (can be NAN if not applicable)
} t_lc_match;
typedef struct
{
freq_t Hz;
float R0;
// L-Network solution structure
t_lc_match matches[4];
int16_t num_matches;
} lc_match_array_t;
// Size = 60 bytes
static lc_match_array_t *lc_match_array = (lc_match_array_t *)measure_memory;
// Calculate two solutions for ZL where (R + X * X / R) > R0
static void lc_match_calc_hi(float R0, float RL, float XL, t_lc_match *matches) {
float xp[2];
const float a = R0 - RL;
const float b = 2.0f * XL * R0;
const float c = R0 * (XL * XL + RL * RL);
match_quadratic_equation(a, b, c, xp);
// found two impedances parallel to load
//
// now calculate serial impedances
const float XL1 = XL + xp[0];
matches[0].xs = xp[0] * xp[0] * XL1 / (RL * RL + XL1 * XL1) - xp[0];
matches[0].xps = 0.0f;
matches[0].xpl = xp[0];
const float XL2 = XL + xp[1];
matches[1].xs = xp[1] * xp[1] * XL2 / (RL * RL + XL2 * XL2) - xp[1];
matches[1].xps = 0.0f;
matches[1].xpl = xp[1];
}
// Calculate two solutions for ZL where R < R0
static void lc_match_calc_lo(float R0, float RL, float XL, t_lc_match *matches) {
float xs[2];
// Calculate Xs
const float a = 1.0f;
const float b = 2.0f * XL;
const float c = RL * RL + XL * XL - R0 * RL;
match_quadratic_equation(a, b, c, xs);
// got two serial impedances that change ZL to the Y.real = 1/R0
//
// now calculate impedances parallel to source
const float XL1 = XL + xs[0];
const float RL1 = RL - R0;
matches[0].xs = xs[0];
matches[0].xps = - R0 * R0 * XL1 / (RL1 * RL1 + XL1 * XL1);
matches[0].xpl = 0.0f;
const float XL2 = XL + xs[1];
matches[1].xs = xs[1];
matches[1].xps = - R0 * R0 * XL2 / (RL1 * RL1 + XL2 * XL2);
matches[1].xpl = 0.0f;
}
static int16_t lc_match_calc(int index) {
const float R0 = lc_match_array->R0;
// compute the impedance at the chosen frequency
const float *coeff = measured[0][index];
const float RL = resistance(index, coeff);
const float XL = reactance(index, coeff);
if (RL <= 0.5f)
return -1;
const float q_factor = XL / RL;
const float vswr = swr(index, coeff);
// no need for any matching
if (vswr <= 1.1f || q_factor >= 100.0f)
return 0;
// only one solution is enough: just a serial reactance
// this gives SWR < 1.1 if R is within the range 0.91 .. 1.1 of R0
t_lc_match *matches = lc_match_array->matches;
if ((RL * 1.1f) > R0 && RL < (R0 * 1.1f)) {
matches[0].xpl = 0.0f;
matches[0].xps = 0.0f;
matches[0].xs = -XL;
return 1;
}
int16_t n = 0;
if (RL >= R0 || RL * RL + XL * XL > R0 * RL) {
lc_match_calc_hi(R0, RL, XL, &matches[0]); // Compute Hi-Z solutions
if (RL >= R0) return 2; // Only Hi-Z solution present
n = 2;
}
lc_match_calc_lo(R0, RL, XL, &matches[n]); // Compute Lo-Z solutions
return n + 2;
}
static void prepare_lc_match(uint8_t mode, uint8_t update_mask) {
(void)mode;
(void)update_mask;
// Made calculation only one time for current sweep and frequency
freq_t freq = get_marker_frequency(active_marker);
if (freq == 0)// || lc_match_array->Hz == freq)
return;
lc_match_array->R0 = PORT_Z; // 50.0f
lc_match_array->Hz = freq;
// compute the possible LC matches
lc_match_array->num_matches = lc_match_calc(markers[active_marker].index);
// Mark to redraw area under L/C match text
invalidate_rect(STR_MEASURE_X , STR_MEASURE_Y,
STR_MEASURE_X + 3 * STR_MEASURE_WIDTH, STR_MEASURE_Y + (4 + 2) * STR_MEASURE_HEIGHT);
}
//
static void lc_match_x_str(uint32_t FHz, float X, int xp, int yp)
{
if (isnan(X) || 0.0f == X || -0.0f == X)
return;
char type;
#if 0
float val;
if (X < 0.0f) {val = 1.0f / (2.0f * VNA_PI * FHz * -X); type = S_FARAD[0];}
else {val = X / (2.0f * VNA_PI * FHz); type = S_HENRY[0];}
#else
if (X < 0.0f) {X = -1.0f / X; type = S_FARAD[0];}
else { type = S_HENRY[0];}
float val = X / ((2.0f * VNA_PI) * FHz);
#endif
cell_printf(xp, yp, "%4.2F%c", val, type);
}
// Render L/C match to cell
static void draw_lc_match(int xp, int yp) {
cell_printf(xp, yp, "L/C match for source Z0 = %0.1f" S_OHM, lc_match_array->R0);
#if 0
yp += STR_MEASURE_HEIGHT;
cell_printf(xp, yp, "%q" S_Hz " %0.1f %c j%0.1f" S_OHM, match_array->Hz, match_array->RL, (match_array->XL >= 0) ? '+' : '-', vna_fabsf(match_array->XL));
#endif
yp += STR_MEASURE_HEIGHT;
if (yp >= CELLHEIGHT) return;
if (lc_match_array->num_matches < 0)
cell_printf(xp, yp, "No LC match for this");
else if (lc_match_array->num_matches == 0)
cell_printf(xp, yp, "No need for LC match");
else {
cell_printf(xp , yp, "Src shunt" );
cell_printf(xp + STR_MEASURE_WIDTH, yp, "Series" );
cell_printf(xp + 2*STR_MEASURE_WIDTH, yp, "Load shunt");
for (int i = 0; i < lc_match_array->num_matches; i++){
yp += STR_MEASURE_HEIGHT;
if (yp >= CELLHEIGHT) return;
lc_match_x_str(lc_match_array->Hz, lc_match_array->matches[i].xps, xp , yp);
lc_match_x_str(lc_match_array->Hz, lc_match_array->matches[i].xs , xp + STR_MEASURE_WIDTH, yp);
lc_match_x_str(lc_match_array->Hz, lc_match_array->matches[i].xpl, xp + 2*STR_MEASURE_WIDTH, yp);
}
}
}
#endif // __USE_LC_MATCHING__
#ifdef __S21_MEASURE__
typedef struct {
const char *header;
freq_t freq; // resonant frequency
freq_t freq1; // fp
float l;
float c;
float c1; // capacitor parallel
float r;
float q; // Q factor
// freq_t f1;
// freq_t f2;
// float tan45;
} s21_analysis_t;
static s21_analysis_t *s21_measure = (s21_analysis_t *)measure_memory;
static float s21pow2(uint16_t i) {
const float re = measured[1][i][0]; // S21 real
const float im = measured[1][i][1]; // S21 imaginary
return re*re+im*im; // S21^2
}
static float s21tan(uint16_t i) {
const float re = measured[1][i][0]; // S21 real
const float im = measured[1][i][1]; // S21 imaginary
return im/re; // tan(S21)
}
static float s21logmag(uint16_t i) {
return logmag(i, measured[1][i]);
}
// Phase Shift Measurement
// https://www.mikrocontroller.net/attachment/473317/Crystal_Motional_Parameters.pdf
static void analysis_lcshunt(void) {
uint16_t xp = 0, x2;
s21_measure->header = "LC-SHUNT";
// Minimum search
float ypeak = search_peak_value(&xp, s21pow2, MEASURE_SEARCH_MIN);
// peak frequency, R
float att = vna_sqrtf(ypeak);
s21_measure->r = config._measure_r * att / (2.0f * (1.0f - att));
if(s21_measure->r < 0.0f) return;
set_marker_index(0, xp);
float tan45 = config._measure_r/(config._measure_r + 4.0f * s21_measure->r);
// s21_measure->tan45 = tan45;
// -45 degree search at left
x2 = xp;
float f1 = measure_search_value(&x2, -tan45, s21tan, MEASURE_SEARCH_LEFT, 1);
if (f1 == 0) return;
// +45 degree search at right
x2 = xp;
float f2 = measure_search_value(&x2, tan45, s21tan, MEASURE_SEARCH_RIGHT, 2);
if (f2 == 0) return;
// L, C, Q calculations
float bw = f2 - f1;
float fpeak = vna_sqrtf(f2 * f1);
s21_measure->freq = fpeak;
s21_measure->q = fpeak / bw;
s21_measure->l = s21_measure->r / ((2.0f * VNA_PI) * bw);
s21_measure->c = bw / ((2.0f * VNA_PI) * fpeak * fpeak * s21_measure->r);
}
static void analysis_lcseries(void) {
uint16_t xp=0, x2;
s21_measure->header = "LC-SERIES";
// Peak value and it frequency index search
float ypeak = search_peak_value(&xp, s21pow2, MEASURE_SEARCH_MAX);
if (xp == 0) return; // peak not found
// motional resistance, Rm
s21_measure->r = 2 * config._measure_r * (1.0f / vna_sqrtf(ypeak) - 1.0f);
if(s21_measure->r < 0) return;
set_marker_index(0, xp);
const float tan45 = 1.0f; // tang(45) = 1.0f
// Lookup +45 phase at left of xp index
x2 = xp;
float f1 = measure_search_value(&x2, tan45, s21tan, MEASURE_SEARCH_LEFT, 1);
if (f1 == 0) return; // not found
// Lookup -45 phase at right of xp index
x2 = xp;
float f2 = measure_search_value(&x2, -tan45, s21tan, MEASURE_SEARCH_RIGHT, 2);
if (f2 == 0) return; // not found
// L, C, Q calculation
float bw = f2 - f1;
float fpeak = vna_sqrtf(f2 * f1);
// The total resistance, REFF, seen by the crystal is the sum of the load resistance (input and output) and the motional resistance, Rm:
float reff = 2.0f * config._measure_r + s21_measure->r;
s21_measure->freq = fpeak;
s21_measure->l = reff / ((2.0f * VNA_PI) * bw);
s21_measure->c = bw / ((2.0f * VNA_PI) * fpeak * fpeak * reff);
// q = 2 * pi * Fp * Ls / R
s21_measure->q = (2.0f * VNA_PI) * fpeak * s21_measure->l / s21_measure->r;
// s21_measure->f1 = f1;
// s21_measure->f2 = f2;
}
static void analysis_xtalseries(void) {
analysis_lcseries();
s21_measure->header = "XTAL-SERIES";
// search S21 min
uint16_t xp=0;
search_peak_value(&xp, s21pow2, MEASURE_SEARCH_MIN);
if (xp == 0) return;
set_marker_index(3, xp);
freq_t freq1 = getFrequency(xp);
if(freq1 < s21_measure->freq) return;
s21_measure->freq1 = freq1;
// df = f * c / (2 * c1) => c1 = f * c / (2 * df)
s21_measure->c1 = s21_measure->c * s21_measure->freq / (2.0f * (s21_measure->freq1 - s21_measure->freq));
}
static void draw_serial_result(int xp, int yp) {
cell_printf(xp, yp, s21_measure->header);
yp+=STR_MEASURE_HEIGHT;
if (s21_measure->freq == 0 && s21_measure->freq1 == 0) {
cell_printf(xp, yp, "Not found");
return;
}
if (s21_measure->freq)
{
cell_printf(xp, yp , "Fs=%q" S_Hz, s21_measure->freq);
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Lm=%F" S_HENRY " Cm=%F" S_FARAD " Rm=%F" S_OHM, s21_measure->l, s21_measure->c, s21_measure->r);
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Q=%.3f", s21_measure->q);
// cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "tan45=%.4f", s21_measure->tan45);
// cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "F1=%q" S_Hz " F2=%q" S_Hz, s21_measure->f1, s21_measure->f2);
}
if (s21_measure->freq1){
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Fp=%q" S_Hz, s21_measure->freq1);
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Cp=%F" S_FARAD, s21_measure->c1);
}
}
static void prepare_series(uint8_t type, uint8_t update_mask) {
(void)update_mask;
uint16_t n;
// for detect completion
s21_measure->freq = 0;
s21_measure->freq1 = 0;
switch (type){
case MEASURE_SHUNT_LC: n = 4; analysis_lcshunt(); break;
case MEASURE_SERIES_LC: n = 4; analysis_lcseries(); break;
case MEASURE_SERIES_XTAL: n = 6; analysis_xtalseries(); break;
default: return;
}
// Prepare for update
invalidate_rect(STR_MEASURE_X , STR_MEASURE_Y,
STR_MEASURE_X + 3 * STR_MEASURE_WIDTH, STR_MEASURE_Y + n * STR_MEASURE_HEIGHT);
markmap_all_markers();
}
enum {_3dB = 0, _6dB, _10dB, _20dB/*, _60dB*/, _end};
static const float filter_att[_end] = {3.0f , 6.0f, 10.0f, 20.0f/*, 60.0f*/};
typedef struct {
float f[_end]; // freq array for -3, -6, -10, -20, -60 dB logmag
float decade;
float octave;
} s21_pass;
typedef struct {
float fmax;
float vmax;
s21_pass lo_pass;
s21_pass hi_pass;
// Band pass filter data
float f_center;
float bw_3dB;
float bw_6dB;
float q;
} s21_filter_measure_t;
static s21_filter_measure_t *s21_filter = (s21_filter_measure_t *)measure_memory;
static void draw_s21_pass(int xp, int yp, s21_pass *p, const char *name) {
cell_printf(xp, yp, name);
if (p->f[_3dB]) cell_printf(xp, yp + STR_MEASURE_HEIGHT, "%.6F" S_Hz, p->f[_3dB]);
if (p->f[_6dB]) cell_printf(xp, yp + 2*STR_MEASURE_HEIGHT, "%.6F" S_Hz, p->f[_6dB]);
yp+= 3 * STR_MEASURE_HEIGHT;
if (p->decade) {
cell_printf(xp, yp , "%F" S_dB "/dec", p->decade);
cell_printf(xp, yp + STR_MEASURE_HEIGHT, "%F" S_dB "/oct", p->octave);
}
}
#define S21_MEASURE_FILTER_THRESHOLD -50.0f
static void draw_filter_result(int xp, int yp){
cell_printf(xp, yp, "S21 FILTER");
if (s21_filter->vmax < S21_MEASURE_FILTER_THRESHOLD) return;
yp+= STR_MEASURE_HEIGHT;
// f: ___.___MHz (xxxdB)
// Bw(-3dB): ___.___MHz
// Bw(-6dB): ___.___MHz
// Q: xxx
if (s21_filter->f_center) {
cell_printf(xp, yp, "f: %.6F" S_Hz " (%F" S_dB ")", s21_filter->f_center, s21_filter->vmax);
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Bw (-%d" S_dB "): %.6F" S_Hz, 3, s21_filter->bw_3dB);
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Bw (-%d" S_dB "): %.6F" S_Hz, 6, s21_filter->bw_6dB);
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Q: %F", s21_filter->q);
} else {
cell_printf(xp, yp, "f: %.6F" S_Hz " (%F" S_dB ")", s21_filter->fmax, s21_filter->vmax);
}
// Lo/Hi pass data show
const int width0 = 3 * STR_MEASURE_WIDTH * 2 / 10; // 1 column width 20%
const int width1 = 3 * STR_MEASURE_WIDTH * 4 / 10; // 2 and 3 column 40%
// 20% | 40% | 40%
// Low-side High-side
// f(-3) ___.___MHz ___.___MHz
// f(-6) ___.___MHz ___.___MHz
// Roll: ___dB/dec ___dB/oct
// ___dB/dec ___dB/oct
if (s21_filter->lo_pass.f[_3dB] || s21_filter->hi_pass.f[_3dB]) {
yp+= STR_MEASURE_HEIGHT;
cell_printf(xp, yp + 1 * STR_MEASURE_HEIGHT, "f(-%d):", 3);
cell_printf(xp, yp + 2 * STR_MEASURE_HEIGHT, "f(-%d):", 6);
cell_printf(xp, yp + 3 * STR_MEASURE_HEIGHT, "Roll:");
xp+= width0;
if (s21_filter->hi_pass.f[_3dB]) {draw_s21_pass(xp, yp, &s21_filter->hi_pass, s21_filter->f_center ? "Low-side" : "High-pass"); xp+= width1; }
if (s21_filter->lo_pass.f[_3dB]) {draw_s21_pass(xp, yp, &s21_filter->lo_pass, s21_filter->f_center ? "High-side" : "Low-pass"); }
}
}
static void find_filter_pass(float max, s21_pass *p, uint16_t idx, int16_t mode) {
// Fill frequency for all in filter_att (-3, -6, -10, -20, -60 dB) logmag
for (int i = 0; i < _end; i++)
p->f[i] = measure_search_value(&idx, max - filter_att[i], s21logmag, mode, i == 0 ? (mode == MEASURE_SEARCH_LEFT ? 1 : 2) : MARKER_INVALID);
// Reset Roll-off data
p->decade = p->octave = 0.0f;
if (p->f[_10dB] != 0 && p->f[_20dB] != 0) {
float k = vna_fabsf(vna_logf(p->f[_20dB]) - vna_logf(p->f[_10dB]));
// decade = delta / log10(f1 / f2) = delta / (log10(f1) - log10(f2)) = delta * log(10) / (log(f1) - log(f2))
p->decade = (10.0f * logf(10.0f)) / k;
// octave = decade * log10(2) = decade * log(2) / log(10) = delta * log(2) / (log(f1) - log(f2))
p->octave = (10.0f * logf( 2.0f)) / k;
}
}
static void prepare_filter(uint8_t type, uint8_t update_mask) {
(void)type;
(void)update_mask;
uint16_t xp = 0;
s21_filter->vmax = search_peak_value(&xp, s21logmag, MEASURE_SEARCH_MAX); // Maximum search
// If maximum < 50dB, no filter detected
if (s21_filter->vmax >= S21_MEASURE_FILTER_THRESHOLD) {
set_marker_index(0, xp); // Put marker on maximum value point
s21_filter->fmax = getFrequency(xp); // Get maximum value frequency
find_filter_pass(s21_filter->vmax, &s21_filter->hi_pass, xp, MEASURE_SEARCH_LEFT); // Search High-pass filter data (or Low side for bandpass)
find_filter_pass(s21_filter->vmax, &s21_filter->lo_pass, xp, MEASURE_SEARCH_RIGHT);// Search Low-pass filter data (or High side for bandpass)
// Calculate Band-pass filter data
s21_filter->f_center = s21_filter->lo_pass.f[_3dB] * s21_filter->hi_pass.f[_3dB]; // Center frequency (if 0, one or both points not found)
if (s21_filter->f_center) {
s21_filter->bw_3dB = s21_filter->lo_pass.f[_3dB] - s21_filter->hi_pass.f[_3dB];
s21_filter->bw_6dB = s21_filter->lo_pass.f[_6dB] - s21_filter->hi_pass.f[_6dB];
s21_filter->f_center = vna_sqrtf(s21_filter->f_center);
s21_filter->q = s21_filter->f_center / s21_filter->bw_3dB;
}
}
// Prepare for update
invalidate_rect(STR_MEASURE_X , STR_MEASURE_Y,
STR_MEASURE_X + 3 * STR_MEASURE_WIDTH, STR_MEASURE_Y + 10 * STR_MEASURE_HEIGHT);
}
#endif // __S21_MEASURE__
#ifdef __S11_CABLE_MEASURE__
typedef struct {
float freq;
float R;
float len;
float loss;
float mloss;
float vf;
float C0;
float a, b, c;
} s11_cable_measure_t;
static s11_cable_measure_t *s11_cable = (s11_cable_measure_t *)measure_memory;
float real_cable_len = 0.0f;
static float s11imag(uint16_t i) {
return measured[0][i][1];
}
static float s11loss(uint16_t i) {
return -0.5f * logmag(i, measured[0][i]);
}
static float s11index(uint16_t i) {
return vna_sqrtf(getFrequency(i) * 1e-9f);
}
static void draw_s11_cable(int xp, int yp){
cell_printf(xp, yp, "S11 CABLE");
if (s11_cable->R){
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Z0 = %F" S_OHM, s11_cable->R);
// cell_printf(xp, yp+=FONT_STR_HEIGHT, "C0 = %F" S_FARAD, s11_cable->C0);
}
if (s11_cable->vf)
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "VF=%.2f%% (Length = %F" S_METRE ")", s11_cable->vf, real_cable_len);
else if (s11_cable->len)
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Length = %F" S_METRE " (VF=%d%%)", s11_cable->len, velocity_factor);
//cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Loss = %F" S_dB " at %.4F" S_Hz, s11_cable->loss, s11_cable->freq);
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Loss = %F" S_dB " at %.4F" S_Hz, s11_cable->mloss, s11_cable->freq);
float l = s11_cable->vf ? real_cable_len : s11_cable->len;
if (l) cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Att (dB/100m): %F" S_dB " at %.4F" S_Hz, s11_cable->mloss * 100.0f / l, (float)s11_cable->freq);
// cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "a: %.6F, b: %.6F, c: %.6F", s11_cable->a, s11_cable->b, s11_cable->c);
}
static void prepare_s11_cable(uint8_t type, uint8_t update_mask) {
(void)type;
freq_t f1;
if (update_mask & MEASURE_UPD_SWEEP) {
s11_cable->R = 0.0f;
s11_cable->len = 0.0f;
s11_cable->vf = 0.0f;
uint16_t x = 0;
f1 = measure_search_value(&x, 0, s11imag, MEASURE_SEARCH_RIGHT, MARKER_INVALID);
if (f1){
float electric_lengh = (SPEED_OF_LIGHT / 400.0f) / f1;
s11_cable->len = velocity_factor * electric_lengh;
if (real_cable_len != 0.0f) s11_cable->vf = real_cable_len / electric_lengh;
float data[2];
if (measure_get_value(0, f1/2, data)){
s11_cable->R = vna_fabsf(reactance(0, data));
// s11_cable->C0 = velocity_factor / (100.0f * SPEED_OF_LIGHT * s11_cable->R);
}
}
parabolic_regression(sweep_points, s11index, s11loss, &s11_cable->a);
}
if ((update_mask & MEASURE_UPD_ALL) && active_marker != MARKER_INVALID) {
int idx = markers[active_marker].index;
// s11_cable->loss = s11loss(idx);
s11_cable->freq = (float)getFrequency(idx);
float f = s11_cable->freq * 1e-9f;
s11_cable->mloss = s11_cable->a + s11_cable->b * vna_sqrtf(f) + s11_cable->c * f;
}
// Prepare for update
invalidate_rect(STR_MEASURE_X , STR_MEASURE_Y,
STR_MEASURE_X + 3 * STR_MEASURE_WIDTH, STR_MEASURE_Y + 6 * STR_MEASURE_HEIGHT);
}
#endif // __S11_CABLE_MEASURE__
#ifdef __S11_RESONANCE_MEASURE__
#define MEASURE_RESONANCE_COUNT 6
typedef struct {
struct {
freq_t f;
float r;
float x;
} data[MEASURE_RESONANCE_COUNT];
uint8_t count;
} s11_resonance_measure_t;
static s11_resonance_measure_t *s11_resonance = (s11_resonance_measure_t *)measure_memory;
static float s11_resonance_value(uint16_t i) {
return measured[0][i][1];
}
static float s11_resonance_min(uint16_t i) {
return fabsf(reactance(i, measured[0][i]));
}
static void draw_s11_resonance(int xp, int yp) {
cell_printf(xp, yp, "S11 RESONANCE");
if (s11_resonance->count == 0) {
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "Not found");
return;
}
for (int i = 0; i < s11_resonance->count; i++)
cell_printf(xp, yp+=STR_MEASURE_HEIGHT, "%q" S_Hz ", %F%+jF" S_OHM, s11_resonance->data[i].f, s11_resonance->data[i].r, s11_resonance->data[i].x);
}
static bool add_resonance_value(int i, uint16_t x, freq_t f) {
float data[2];
if (measure_get_value(0, f, data)) {
s11_resonance->data[i].f = f;
//set_marker_index(i, x);
s11_resonance->data[i].r = resistance(x, data);
s11_resonance->data[i].x = reactance(x, data);
return true;
}
return false;
}
static void prepare_s11_resonance(uint8_t type, uint8_t update_mask) {
(void)type;
if (update_mask & MEASURE_UPD_SWEEP) {
int i;
freq_t f;
uint16_t x = 0;
// Search resonances (X == 0)
for (i = 0; i < MEASURE_RESONANCE_COUNT && i < MARKERS_MAX;) {
f = measure_search_value(&x, 0.0f, s11_resonance_value, MEASURE_SEARCH_RIGHT, MARKER_INVALID);
if (f == 0) break;
if (add_resonance_value(i, x, f))
i++;
x++;
}
if (i == 0) { // Search minimum position, if resonances not found
x = 0;
search_peak_value(&x, s11_resonance_min, MEASURE_SEARCH_MIN);
if (x && add_resonance_value(0, x, getFrequency(x)))
i = 1;
}
s11_resonance->count = i;
}
// Prepare for update
invalidate_rect(STR_MEASURE_X , STR_MEASURE_Y,
STR_MEASURE_X + 3 * STR_MEASURE_WIDTH, STR_MEASURE_Y + (MEASURE_RESONANCE_COUNT + 1) * STR_MEASURE_HEIGHT);
}
#endif //__S11_RESONANCE_MEASURE__
#pragma GCC pop_options
#endif // __VNA_MEASURE_MODULE__