/* Copyright (c) 2014-2015, TAKAHASHI Tomohiro (TTRFTECH) edy555@gmail.com * 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. */ #include "ch.h" #ifdef TINYSA_F303 #include "adc_F303.h" #endif // Need enable HAL_USE_SPI in halconf.h #define __USE_DISPLAY_DMA__ #define __SA__ //#define __SIMULATION__ //#define __PIPELINE__ #define __SCROLL__ #define __ICONS__ #define __MEASURE__ #define __SELFTEST__ #define __CALIBRATE__ #define __FAST_SWEEP__ // Pre-fill SI4432 RSSI buffer to get fastest sweep in zero span mode //#define __ULTRA__ // Add harmonics mode on low input. //#define __ULTRA_SA__ // Adds ADF4351 control for extra high 1st IF stage #define __SPUR__ // Does spur reduction by shifting IF /* * main.c */ #ifdef __SA__ #define POINTS_COUNT 290 #define MARKER_COUNT 4 #define TRACES_MAX 3 #define TRACE_AGE 3 #define TRACE_ACTUAL 2 #define TRACE_STORED 1 #define TRACE_TEMP 0 // #define age_t measured[TRACE_AGE] #define stored_t measured[TRACE_STORED] #define actual_t measured[TRACE_ACTUAL] #define temp_t measured[TRACE_TEMP] #define CORRECTION_POINTS 10 // Frequency dependent level correction table entries typedef float measurement_t[TRACES_MAX][POINTS_COUNT]; extern measurement_t measured; #endif #ifdef __VNA__ // Minimum frequency set #define START_MIN 50000 // Maximum frequency set #define STOP_MAX 2700000000U // Frequency offset (sin_cos table in dsp.c generated for this offset, if change need create new table) #define FREQUENCY_OFFSET 5000 // Speed of light const #define SPEED_OF_LIGHT 299792458 // pi const #define VNA_PI 3.14159265358979323846 #define POINTS_COUNT 101 extern float measured[2][POINTS_COUNT][2]; #define CAL_LOAD 0 #define CAL_OPEN 1 #define CAL_SHORT 2 #define CAL_THRU 3 #define CAL_ISOLN 4 #define CALSTAT_LOAD (1<<0) #define CALSTAT_OPEN (1<<1) #define CALSTAT_SHORT (1<<2) #define CALSTAT_THRU (1<<3) #define CALSTAT_ISOLN (1<<4) #define CALSTAT_ES (1<<5) #define CALSTAT_ER (1<<6) #define CALSTAT_ET (1<<7) #define CALSTAT_ED CALSTAT_LOAD #define CALSTAT_EX CALSTAT_ISOLN #define CALSTAT_APPLY (1<<8) #define CALSTAT_INTERPOLATED (1<<9) #define ETERM_ED 0 /* error term directivity */ #define ETERM_ES 1 /* error term source match */ #define ETERM_ER 2 /* error term refrection tracking */ #define ETERM_ET 3 /* error term transmission tracking */ #define ETERM_EX 4 /* error term isolation */ #define DOMAIN_MODE (1<<0) #define DOMAIN_FREQ (0<<0) #define DOMAIN_TIME (1<<0) #define TD_FUNC (0b11<<1) #define TD_FUNC_BANDPASS (0b00<<1) #define TD_FUNC_LOWPASS_IMPULSE (0b01<<1) #define TD_FUNC_LOWPASS_STEP (0b10<<1) #define TD_WINDOW (0b11<<3) #define TD_WINDOW_NORMAL (0b00<<3) #define TD_WINDOW_MINIMUM (0b01<<3) #define TD_WINDOW_MAXIMUM (0b10<<3) #define FFT_SIZE 256 void cal_collect(int type); void cal_done(void); #endif #define MAX_FREQ_TYPE 5 enum stimulus_type { ST_START=0, ST_STOP, ST_CENTER, ST_SPAN, ST_CW }; void set_sweep_points(uint16_t points); void update_frequencies(void); void set_sweep_frequency(int type, uint32_t frequency); uint32_t get_sweep_frequency(int type); void my_microsecond_delay(int t); double my_atof(const char *p); int shell_printf(const char *fmt, ...); void toggle_sweep(void); void toggle_mute(void); void load_default_properties(void); enum { AV_OFF, AV_MIN, AV_MAX_HOLD, AV_MAX_DECAY, AV_4, AV_16 }; enum { M_LOW, M_HIGH, M_GENLOW, M_GENHIGH, M_ULTRA }; enum { MO_NONE, MO_AM_1kHz, MO_AM_10Hz, MO_NFM, MO_WFM, MO_EXTERNAL, }; #define MODE_OUTPUT(x) ((x) == M_GENLOW || (x) == M_GENHIGH ) #ifdef __ULTRA__ #define MODE_INPUT(x) ((x) == M_LOW || (x) == M_HIGH || (x) == M_ULTRA ) #else #define MODE_INPUT(x) ((x) == M_LOW || (x) == M_HIGH ) #endif #define MODE_HIGH(x) ((x) == M_HIGH || (x) == M_GENHIGH ) #define MODE_LOW(x) ((x) == M_LOW || (x) == M_GENLOW ) #define MODE_SELECT(x) (MODE_HIGH(x) ? 1 : 0) #define SWEEP_ENABLE 0x01 #define SWEEP_ONCE 0x02 #define SWEEP_CALIBRATE 0x04 #define SWEEP_SELFTEST 0x08 #define SWEEP_REMOTE 0x10 //#define SWEEP_FACTORY 0x20 extern int8_t sweep_mode; extern bool completed; extern const char *info_about[]; // ------------------------------- sa_core.c ---------------------------------- void reset_settings(int); //void ui_process_touch(void); void SetPowerGrid(int); void SetRefLevel(float); void set_refer_output(int); void toggle_below_IF(void); int get_refer_output(void); void set_attenuation(float); float get_attenuation(void); void set_harmonic(int); //extern int setting.harmonic; int search_is_greater(void); void set_auto_attenuation(void); void set_auto_reflevel(int); int is_paused(void); void set_actual_power(float); void SetGenerate(int); void set_RBW(uint32_t rbw_x10); void set_drive(int d); void set_IF(int f); void set_step_delay(int t); void set_offset_delay(int t); void set_repeat(int); void set_level_sweep(float); void set_level(float); void set_sweep_time_us(uint32_t); //extern int setting.repeat; //extern int setting.rbw; #ifdef __SPUR__ //extern int setting.spur; void set_spur(int v); #endif void set_average(int); int GetAverage(void); //extern int setting.average; void set_storage(void); void set_clear_storage(void); void set_subtract_storage(void); void toggle_normalize(void); void toggle_waterfall(void); void set_mode(int); int GetMode(void); void set_reflevel(float); void user_set_reflevel(float); #define REFLEVEL_MAX 9999.0 #define REFLEVEL_MIN 1.0e-12 void set_scale(float); void user_set_scale(float); void AllDirty(void); void MenuDirty(void); void toggle_LNA(void); void toggle_AGC(void); void redrawHisto(void); void self_test(int); void set_decay(int); void set_noise(int); void toggle_tracking_output(void); extern int32_t frequencyExtra; void set_10mhz(uint32_t); void set_modulation(int); //extern int setting.modulation; void set_measurement(int); // extern int settingSpeed; //extern int setting.step_delay; void sweep_remote(void); #ifdef __VNA__ /* * dsp.c */ // 5ms @ 48kHz #define AUDIO_BUFFER_LEN 96 extern int16_t rx_buffer[]; #define STATE_LEN 32 #define SAMPLE_LEN 48 #ifdef ENABLED_DUMP extern int16_t ref_buf[]; extern int16_t samp_buf[]; #endif void dsp_process(int16_t *src, size_t len); void reset_dsp_accumerator(void); void calculate_gamma(float *gamma); void fetch_amplitude(float *gamma); void fetch_amplitude_ref(float *gamma); #endif #ifdef __VNA__ /* * tlv320aic3204.c */ extern void tlv320aic3204_init(void); extern void tlv320aic3204_set_gain(int lgain, int rgain); extern void tlv320aic3204_select(int channel); #endif /* * plot.c */ // Offset of plot area #define OFFSETX 30 #define OFFSETY 0 #define NGRIDY 10 // GRIDX calculated depends from frequency span #ifdef __SCROLL__ extern uint16_t _grid_y; #define GRIDY _grid_y #define HEIGHT_SCROLL 180 #define HEIGHT_NOSCROLL 230 #define SCROLL_GRIDY (HEIGHT_SCROLL / NGRIDY) #define NOSCROLL_GRIDY (HEIGHT_NOSCROLL / NGRIDY) #else #define GRIDY (230 / NGRIDY) #endif #define WIDTH (LCD_WIDTH - 1 - OFFSETX) #define HEIGHT (GRIDY*NGRIDY) #define CELLWIDTH (32) #define CELLHEIGHT (32) #define FREQUENCIES_XPOS1 OFFSETX #define FREQUENCIES_XPOS2 200 #define FREQUENCIES_YPOS (LCD_HEIGHT-7) // #define CELLOFFSETX 0 #define AREA_WIDTH_NORMAL (CELLOFFSETX + WIDTH + 1) #define AREA_HEIGHT_NORMAL ( HEIGHT + 1) #define GRID_X_TEXT (AREA_WIDTH_NORMAL - 7*5) // Smith/polar chart #define P_CENTER_X (CELLOFFSETX + WIDTH/2) #define P_CENTER_Y (HEIGHT/2) #define P_RADIUS (HEIGHT/2) // Menu Button // Maximum menu buttons count #define MENU_BUTTON_MAX 8 #define MENU_BUTTON_WIDTH 80 #define MENU_BUTTON_HEIGHT 28 #define MENU_BUTTON_BORDER 1 #define KEYBOARD_BUTTON_BORDER 2 #define FORM_BUTTON_BORDER 2 // Form button (at center screen better be less LCD_WIDTH - 2*OFFSETX) #define MENU_FORM_WIDTH 256 // Num Input height at bottom #define NUM_INPUT_HEIGHT 32 extern int16_t area_width; extern int16_t area_height; // font extern const uint8_t x5x7_bits []; extern const uint8_t x7x11b_bits []; #define FONT_GET_DATA(ch) (&x5x7_bits[ch*7]) #define FONT_GET_WIDTH(ch) (8-(x5x7_bits[ch*7]&7)) #define FONT_MAX_WIDTH 7 #define FONT_GET_HEIGHT 7 #define FONT_STR_HEIGHT 8 #define bFONT_GET_DATA(ch) (&x7x11b_bits[ch*11]) #define bFONT_GET_WIDTH(ch) (8-(x7x11b_bits[ch*11]&7)) #define bFONT_MAX_WIDTH 8 #define bFONT_WIDTH 7 #define bFONT_GET_HEIGHT 11 #define bFONT_STR_HEIGHT 11 extern const uint16_t numfont16x22[]; #define NUM_FONT_GET_DATA(ch) (&numfont16x22[ch*22]) #define NUM_FONT_GET_WIDTH 16 #define NUM_FONT_GET_HEIGHT 22 #if 1 #define KP_WIDTH ((LCD_WIDTH) / 4)// numeric keypad button width #define KP_HEIGHT ((LCD_HEIGHT - NUM_INPUT_HEIGHT) / 4) // numeric keypad button height // Key x, y position (0 - 15) on screen #define KP_GET_X(posx) ((posx) * KP_WIDTH) // numeric keypad left #define KP_GET_Y(posy) ((posy) * KP_HEIGHT) // numeric keypad top #else #define KP_WIDTH (LCD_HEIGHT/5) #define KP_HEIGHT (LCD_HEIGHT/5) // Key x, y position (0 - 15) on screen #define KP_GET_X(posx) ((posx)*KP_WIDTH + (LCD_WIDTH-MENU_BUTTON_WIDTH-5-KP_WIDTH*4)) #define KP_GET_Y(posy) ((posy)*KP_HEIGHT + 12 ) #endif #define S_DELTA "\004" #define S_DEGREE "\037" #define S_SARROW "\030" #define S_INFINITY "\031" #define S_LARROW "\032" #define S_RARROW "\033" #define S_PI "\034" #define S_MICRO "\035" #define S_OHM "\036" // trace #define MAX_TRACE_TYPE 12 enum trace_type { TRC_LOGMAG=0, TRC_PHASE, TRC_DELAY, TRC_SMITH, TRC_POLAR, TRC_LINEAR, TRC_SWR, TRC_REAL, TRC_IMAG, TRC_R, TRC_X, TRC_OFF }; // Mask for define rectangular plot #define RECTANGULAR_GRID_MASK ((1<, // LINMAG: SCALE, REFPOS, REFVAL // SWR: SCALE, REFPOS, REFVAL // Electrical Delay // Phase #define MAX_UNIT_TYPE 4 enum unit_type { U_DBM=0, U_DBMV, U_DBUV, U_VOLT, U_WATT, U_DBC // dBc only for displaying delta marker info }; #define UNIT_IS_LINEAR(T) ( T >= U_VOLT ? true : false) #define UNIT_IS_LOG(T) ( T >= U_VOLT ? false : true) float value(float); typedef struct trace { uint8_t enabled; uint8_t type; uint8_t channel; uint8_t reserved; float scale; float refpos; } trace_t; #define FREQ_MODE_START_STOP 0x0 #define FREQ_MODE_CENTER_SPAN 0x1 #define FREQ_MODE_DOTTED_GRID 0x2 typedef struct config { int32_t magic; uint16_t dac_value; uint16_t grid_color; uint16_t menu_normal_color; uint16_t menu_active_color; uint16_t trace_color[TRACES_MAX]; int16_t touch_cal[4]; int8_t freq_mode; #ifdef __VNA__ uint32_t harmonic_freq_threshold; #endif uint16_t vbat_offset; int16_t low_level_offset; int16_t high_level_offset; uint32_t correction_frequency[CORRECTION_POINTS]; float correction_value[CORRECTION_POINTS]; uint32_t deviceid; // uint8_t _reserved[22]; uint32_t checksum; } config_t; extern config_t config; //#define settingLevelOffset config.level_offset int get_level_offset(void); void set_trace_type(int t, int type); void set_trace_channel(int t, int channel); void set_trace_scale(float scale); void set_trace_refpos(float refpos); float get_trace_scale(int t); float get_trace_refpos(int t); const char *get_trace_typename(int t); extern int in_selftest; #ifdef __VNA void set_electrical_delay(float picoseconds); float get_electrical_delay(void); float groupdelay_from_array(int i, float array[POINTS_COUNT][2]); #endif // marker enum { M_NORMAL=0,M_REFERENCE=1, M_DELTA=2, M_NOISE=4, M_TRACKING=8, M_DELETE=16 // Tracking must be last. }; enum { M_DISABLED = false, M_ENABLED = true }; typedef struct { int8_t enabled; int8_t mtype; int16_t index; uint32_t frequency; } marker_t; #define MARKERS_MAX 4 extern int8_t previous_marker; extern int8_t marker_tracking; void plot_init(void); void update_grid(void); void request_to_redraw_grid(void); void redraw_frame(void); //void redraw_all(void); void request_to_draw_cells_behind_menu(void); void request_to_draw_cells_behind_numeric_input(void); void redraw_marker(int marker); void markmap_all_markers(void); void plot_into_index(measurement_t measured); void force_set_markmap(void); void draw_frequencies(void); void draw_all(bool flush); void draw_cal_status(void); //void markmap_all_markers(void); void marker_position(int m, int t, int *x, int *y); int search_nearest_index(int x, int y, int t); void set_marker_search(int mode); int marker_search(void); int marker_search_left(int from); int marker_search_right(int from); int marker_search_left_max(int from); int marker_search_right_max(int from); int marker_search_left_min(int from); int marker_search_right_min(int from); // _request flag for update screen #define REDRAW_CELLS (1<<0) #define REDRAW_FREQUENCY (1<<1) #define REDRAW_CAL_STATUS (1<<2) #define REDRAW_MARKER (1<<3) #define REDRAW_BATTERY (1<<4) #define REDRAW_AREA (1<<5) #define REDRAW_TRIGGER (1<<6) extern volatile uint8_t redraw_request; /* * ili9341.c */ // SPI bus revert byte order //gggBBBbb RRRrrGGG #define byteReverse16(x) (uint16_t)(((x) << 8) & 0xff00) | (((x) >> 8) & 0xff) #define RGB565(r,g,b) byteReverse16( ((((uint16_t)(r))<<8)&0b1111100000000000) | ((((uint16_t)(g))<<3)&0b0000011111100000) | ((((uint16_t)(b))>>3)&0b0000000000011111) ) //#define RGB565(r,g,b) ( (((g)&0x1c)<<11) | (((b)&0xf8)<<5) | ((r)&0xf8) | (((g)&0xe0)>>5) ) #define RGBHEX(hex) ( (((hex)&0x001c00)<<3) | (((hex)&0x0000f8)<<5) | (((hex)&0xf80000)>>16) | (((hex)&0x00e000)>>13) ) // Define size of screen buffer in pixels (one pixel 16bit size) #define SPI_BUFFER_SIZE (CELLWIDTH*CELLHEIGHT) #define LCD_WIDTH 320 #define LCD_HEIGHT 240 #define DEFAULT_FG_COLOR RGB565(255,255,255) #define DEFAULT_BG_COLOR RGB565( 0, 0, 0) #define DARK_GREY RGB565(140,140,140) #define LIGHT_GREY RGB565(220,220,220) #define DEFAULT_GRID_COLOR RGB565(128,128,128) #define DEFAULT_GRID_VALUE_COLOR RGB565(196,196,196) #define DEFAULT_MENU_COLOR RGB565(255,255,255) #define DEFAULT_MENU_TEXT_COLOR RGB565( 0, 0, 0) #define DEFAULT_MENU_ACTIVE_COLOR RGB565(180,255,180) #define DEFAULT_TRACE_1_COLOR RGB565(255, 0, 0) /* RGB565(255,255, 0) */ #define DEFAULT_TRACE_2_COLOR RGB565( 0,255, 0)/* RGB565( 0,255,255) */ #define DEFAULT_TRACE_3_COLOR RGB565(255,255, 0)/* RGB565( 0,255, 0) */ #define DEFAULT_TRIGGER_COLOR RGB565( 0, 0,255)/* RGB565( 0 0,255) */ //#define DEFAULT_TRACE_4_COLOR RGB565(255, 0,255) #define DEFAULT_NORMAL_BAT_COLOR RGB565( 31,227, 0) #define DEFAULT_LOW_BAT_COLOR RGB565(255, 0, 0) #define DEFAULT_SPEC_INPUT_COLOR RGB565(128,255,128); #define BRIGHT_COLOR_BLUE RGB565(0,0,255) #define BRIGHT_COLOR_RED RGB565(255,128,128) #define BRIGHT_COLOR_GREEN RGB565(0,255,0) extern uint16_t foreground_color; extern uint16_t background_color; extern uint16_t spi_buffer[SPI_BUFFER_SIZE]; void ili9341_init(void); void ili9341_test(int mode); void ili9341_bulk(int x, int y, int w, int h); void ili9341_fill(int x, int y, int w, int h, uint16_t color); #if 1 void ili9341_set_foreground(uint16_t fg); void ili9341_set_background(uint16_t fg); #else #define ili9341_set_foreground(fg) { foreground_color = fg; } #define ili9341_set_background(bg) { background_color = bg;} #endif void ili9341_clear_screen(void); void blit8BitWidthBitmap(uint16_t x, uint16_t y, uint16_t width, uint16_t height, const uint8_t *bitmap); void blit16BitWidthBitmap(uint16_t x, uint16_t y, uint16_t width, uint16_t height, const uint16_t *bitmap); void ili9341_drawchar(uint8_t ch, int x, int y); void ili9341_drawstring(const char *str, int x, int y); void ili9341_drawstring_7x13(const char *str, int x, int y); void ili9341_drawstringV(const char *str, int x, int y); int ili9341_drawchar_size(uint8_t ch, int x, int y, uint8_t size); void ili9341_drawstring_size(const char *str, int x, int y, uint8_t size); void ili9341_drawfont(uint8_t ch, int x, int y); void ili9341_read_memory(int x, int y, int w, int h, int len, uint16_t* out); void ili9341_line(int x0, int y0, int x1, int y1); void show_version(void); /* * flash.c */ typedef struct setting { uint32_t magic; // uint32_t _frequency0; // uint32_t _frequency1; int mode; uint16_t _sweep_points; float attenuate; int auto_attenuation; int atten_step; uint32_t rbw_x10; int below_IF; int average; int show_stored; int subtract_stored; int drive; // 0-7 , 7=+20dBm, 3dB steps int agc; int lna; int auto_reflevel; float reflevel; float scale; int tracking; int modulation; int step_delay; uint32_t frequency_step; int test; int harmonic; int decay; int noise; uint32_t vbw_x10; int tracking_output; int repeat; uint32_t frequency0; uint32_t frequency1; uint32_t frequency_IF; int freq_mode; int measurement; int refer; int spur; trace_t _trace[TRACES_MAX]; marker_t _markers[MARKERS_MAX]; int8_t _active_marker; int8_t unit; float offset; float trigger_level; int trigger_direction; int trigger; int linearity_step; float level; float level_sweep; uint32_t sweep_time_us; systime_t measure_sweep_time_us; uint32_t actual_sweep_time_us; uint32_t additional_step_delay_us; int test_argument; int auto_IF; unsigned int unit_scale_index; float unit_scale; int mute; int step_delay_mode; int offset_delay; int fast_speedup; uint32_t checksum; }setting_t; extern setting_t setting; extern int setting_frequency_10mhz; void reset_settings(int m); #define S_IS_AUTO(x) ((x)&2) #define S_STATE(X) ((X)&1) enum { S_OFF=0, S_ON=1, S_AUTO_OFF=2, S_AUTO_ON=3 }; enum { SD_NORMAL, SD_PRECISE, SD_FAST, SD_MANUAL }; #ifdef __FAST_SWEEP__ #define MINIMUM_SWEEP_TIME 1800U // Minimum sweep time on zero span in uS #else #define MINIMUM_SWEEP_TIME 15000U // Minimum sweep time on zero span in uS #endif #define MAXIMUM_SWEEP_TIME 600000000U // Maximum sweep time uS #define ONE_SECOND_TIME 1000000U // One second uS #define ONE_MS_TIME 1000U // One ms uS #define REPEAT_TIME 111 // Time per extra repeat in uS #define MEASURE_TIME 127 // Time per single point measurement with vbwstep =1 without step delay in uS extern uint32_t frequencies[POINTS_COUNT]; extern const float unit_scale_value[]; extern const char * const unit_scale_text[]; #if 1 #define SAVEAREA_MAX 9 // config save area #define SAVE_CONFIG_ADDR 0x0801B000 // setting_t save area #define SAVE_PROP_CONFIG_0_ADDR 0x0801B800 #define SAVE_PROP_CONFIG_1_ADDR 0x0801C000 #define SAVE_PROP_CONFIG_2_ADDR 0x0801C800 #define SAVE_PROP_CONFIG_3_ADDR 0x0801D000 #define SAVE_PROP_CONFIG_4_ADDR 0x0801D800 #define SAVE_PROP_CONFIG_5_ADDR 0x0801E000 #define SAVE_PROP_CONFIG_6_ADDR 0x0801E800 #define SAVE_PROP_CONFIG_7_ADDR 0x0801F000 #define SAVE_PROP_CONFIG_8_ADDR 0x0801F800 #define SAVE_CONFIG_AREA_SIZE (0x0801F800 - SAVE_CONFIG_ADDR) // Should include all save slots #else #define SAVEAREA_MAX 4 // Begin addr 0x0801C000 #define SAVE_CONFIG_AREA_SIZE 0x00004000 // config save area #define SAVE_CONFIG_ADDR 0x0801C000 // properties_t save area #define SAVE_PROP_CONFIG_0_ADDR 0x0801C800 #define SAVE_PROP_CONFIG_1_ADDR 0x0801D000 #define SAVE_PROP_CONFIG_2_ADDR 0x0801D800 #define SAVE_PROP_CONFIG_3_ADDR 0x0801E000 #define SAVE_PROP_CONFIG_4_ADDR 0x0801e800 #endif #if 0 typedef struct properties { uint32_t magic; preset_t setting; // uint32_t _frequency0; // uint32_t _frequency1; uint16_t _sweep_points; #ifdef __VNA__ uint16_t _cal_status; #endif #ifdef __SA__ // uint32_t _frequency_IF; //IF frequency #endif // uint32_t _frequencies[POINTS_COUNT]; #ifdef __VNA__ float _cal_data[5][POINTS_COUNT][2]; float _electrical_delay; // picoseconds #endif trace_t _trace[TRACES_MAX]; marker_t _markers[MARKERS_MAX]; int8_t _active_marker; #ifdef __VNA__ float _velocity_factor; // % uint8_t _domain_mode; /* 0bxxxxxffm : where ff: TD_FUNC m: DOMAIN_MODE */ uint8_t _marker_smith_format; uint8_t _bandwidth; #endif uint8_t _reserved[2]; uint32_t checksum; } properties_t; #endif //sizeof(properties_t) == 0x1200 #define CONFIG_MAGIC 0x434f4e46 /* 'CONF' */ extern int16_t lastsaveid; //extern properties_t *active_props; //extern properties_t current_props; //#define frequency0 current_props._frequency0 //#define frequency1 current_props._frequency1 #define sweep_points setting._sweep_points #ifdef __VNA__ #define cal_status current_props._cal_status #endif #ifdef __SA__ //#define frequency_IF current_props._frequency_IF #endif //#define frequencies current_props._frequencies #ifdef __VNA__ #define cal_data active_props->_cal_data #define electrical_delay current_props._electrical_delay #endif #define trace setting._trace #define markers setting._markers #define active_marker setting._active_marker #ifdef __VNA__ #define domain_mode current_props._domain_mode #define velocity_factor current_props._velocity_factor #define marker_smith_format current_props._marker_smith_format #define bandwidth current_props._bandwidth #endif #define FREQ_IS_STARTSTOP() (!(setting.freq_mode&FREQ_MODE_CENTER_SPAN)) #define FREQ_IS_CENTERSPAN() (setting.freq_mode&FREQ_MODE_CENTER_SPAN) #define FREQ_IS_CW() (setting.frequency0 == setting.frequency1) int caldata_recall(int id); int caldata_save(int id); //const properties_t *caldata_ref(int id); int config_save(void); int config_recall(void); void clear_all_config_prop_data(void); /* * ui.c */ extern void ui_init(void); extern void ui_process(void); int current_menu_is_form(void); void ui_mode_normal(void); void ui_mode_menu(void); void menu_push_lowoutput(void); void menu_push_highoutput(void); void menu_move_top(void); void draw_menu(void); int check_touched(void); // Irq operation process set #define OP_NONE 0x00 #define OP_LEVER 0x01 #define OP_TOUCH 0x02 #define OP_CONSOLE 0x04 //#define OP_FREQCHANGE 0x04 extern volatile uint8_t operation_requested; // lever_mode enum lever_mode { LM_MARKER, LM_SEARCH, LM_CENTER, LM_SPAN, LM_EDELAY }; // marker smith value format enum marker_smithvalue { MS_LIN, MS_LOG, MS_REIM, MS_RX, MS_RLC }; typedef struct uistat { float value; // for editing at numeric input area int8_t digit; /* 0~5 */ int8_t digit_mode; int8_t current_trace; /* 0..3 */ // uint32_t previous_value; uint8_t lever_mode; uint8_t marker_delta; uint8_t marker_noise; uint8_t marker_tracking; char text[20]; } uistat_t; typedef struct ui_button { uint16_t fg; uint16_t bg; uint8_t border; int8_t icon; char text[32]; } ui_button_t; extern uistat_t uistat; void ui_init(void); void ui_show(void); void ui_hide(void); void touch_start_watchdog(void); void touch_position(int *x, int *y); void handle_touch_interrupt(void); #define TOUCH_THRESHOLD 2000 void touch_cal_exec(void); void touch_draw_test(void); void enter_dfu(void); /* * adc.c */ #define ADC_TOUCH_X ADC_CHSELR_CHSEL6 #define ADC_TOUCH_Y ADC_CHSELR_CHSEL7 void adc_init(void); uint16_t adc_single_read(uint32_t chsel); void adc_start_analog_watchdogd(uint32_t chsel); void adc_stop(void); void adc_interrupt(void); int16_t adc_vbat_read(void); /* * misclinous */ int plot_printf(char *str, int, const char *fmt, ...); #define PULSE do { palClearPad(GPIOC, GPIOC_LED); palSetPad(GPIOC, GPIOC_LED);} while(0) //extern int setting_attenuate; //extern int settingPowerCal; //extern int setting_step_delay; //extern int actualStepDelay; //extern int setting_mode; // Speed profile definition #define START_PROFILE systime_t time = chVTGetSystemTimeX(); #define RESTART_PROFILE time = chVTGetSystemTimeX(); #define STOP_PROFILE {char string_buf[12];plot_printf(string_buf, sizeof string_buf, "%06d", chVTGetSystemTimeX() - time);ili9341_drawstring(string_buf, 0, FREQUENCIES_YPOS);} #define DELTA_TIME (time = chVTGetSystemTimeX() - time) // Macros for convert define value to string #define STR1(x) #x #define define_to_STR(x) STR1(x) // sa_core.c typedef uint8_t deviceRSSI_t; typedef int16_t pureRSSI_t; // RSSI values conversion macro // External programm zero level settings (need decrease on this value -) #define EXT_ZERO_LEVEL (128) #define DEVICE_TO_PURE_RSSI(rssi) ((rssi)<<4) #define float_TO_PURE_RSSI(rssi) ((rssi)*32) #define PURE_TO_float(rssi) ((rssi)/32.0) extern uint16_t actual_rbw_x10; int get_waterfall(void); void toggle_tracking(void); void reset_calibration(void); void set_reflevel(float); void set_offset(float); void set_unit(int); void set_switches(int); void set_trigger_level(float); void set_trigger(int); void update_rbw(void); void set_fast_speedup(int); //extern int setting_measurement; void self_test(int); //extern int setting_test; void wait_user(void); void calibrate(void); float to_dBm(float); uint32_t calc_min_sweep_time_us(void); pureRSSI_t perform(bool b, int i, uint32_t f, int e); enum { M_OFF, M_IMD, M_OIP3, M_PHASE_NOISE, M_STOP_BAND, M_PASS_BAND, M_LINEARITY }; enum { T_AUTO, T_NORMAL, T_SINGLE, T_DONE, T_UP, T_DOWN }; /*EOF*/