Subversion Repositories FlightCtrl

Rev

Rev 2133 | Details | Compare with Previous | Last modification | View Log | RSS feed

Rev Author Line No. Line
2108 - 1 
#ifndef _ANALOG_H
2 
#define _ANALOG_H
3 
#include <inttypes.h>
4 
#include "configuration.h"
5 
 
6 
/*
7 
 About setting constants for different gyros:
8 
 Main parameters are positive directions and voltage/angular speed gain.
9 
 The "Positive direction" is the rotation direction around an axis where
10 
 the corresponding gyro outputs a voltage > the no-rotation voltage.
11 
 A gyro is considered, in this code, to be "forward" if its positive
12 
 direction is:
13 
 - Nose down for pitch
14 
 - Left hand side down for roll
15 
 - Clockwise seen from above for yaw.
16 
 
17 
 Setting gyro gain correctly: All sensor measurements in analog.c take
18 
 place in a cycle, each cycle comprising all sensors. Some sensors are
19 
 sampled more than once (oversampled), and the results added.
20 
 In the H&I code, the results for pitch and roll are multiplied by 2 (FC1.0)
21 
 or 4 (other versions), offset to zero, low pass filtered and then assigned
22 
 to the "HiResXXXX" and "AdWertXXXXFilter" variables, where XXXX is nick or
23 
 roll. The factor 2 or 4 or whatever is called GYRO_FACTOR_PITCHROLL here.
24 
*/
25 
 
26 
/*
27 
 GYRO_HW_FACTOR is the relation between rotation rate and ADCValue:
28 
 ADCValue [units] =
29 
 rotational speed [deg/s] *
30 
 gyro sensitivity [V / deg/s] *
31 
 amplifier gain [units] *
32 
 1024 [units] /
33 
 3V full range [V]
34 
 
35 
 GYRO_HW_FACTOR is:
36 
 gyro sensitivity [V / deg/s] *
37 
 amplifier gain [units] *
38 
 1024 [units] /
39 
 3V full range [V]
40 
 
41 
 Examples:
42 
 FC1.3 has 0.67 mV/deg/s gyros and amplifiers with a gain of 5.7:
43 
 GYRO_HW_FACTOR = 0.00067 V / deg / s * 5.7 * 1024 / 3V = 1.304 units/(deg/s).
44 
 
45 
 FC2.0 has 6*(3/5) mV/deg/s gyros (they are ratiometric) and no amplifiers:
46 
 GYRO_HW_FACTOR = 0.006 V / deg / s * 1 * 1024 * 3V / (3V * 5V) = 1.2288 units/(deg/s).
47 
 
48 
 My InvenSense copter has 2mV/deg/s gyros and no amplifiers:
49 
 GYRO_HW_FACTOR = 0.002 V / deg / s * 1 * 1024 / 3V = 0.6827 units/(deg/s)
50 
 (only about half as sensitive as V1.3. But it will take about twice the
51 
 rotation rate!)
52 
 
53 
 GYRO_HW_FACTOR is given in the makefile.
54 
*/
55 
 
56 
/*
57 
 * How many samples are added in one ADC loop, for pitch&roll and yaw,
58 
 * respectively. This is = the number of occurences of each channel in the
59 
 * channelsForStates array in analog.c.
60 
 */
61 
#define GYRO_OVERSAMPLING 4
62 
 
63 
/*
64 
 * The product of the 3 above constants. This represents the expected change in ADC value sums for 1 deg/s of rotation rate.
65 
 */
66 
#define GYRO_RATE_FACTOR (GYRO_HW_FACTOR * GYRO_OVERSAMPLING)
67 
 
68 
/*
69 
 * The value of gyro[PITCH/ROLL] for one deg/s = The hardware factor H * the number of samples * multiplier factor.
70 
 * Will be about 10 or so for InvenSense, and about 33 for ADXRS610.
71 
 */
72 
 
73 
/*
74 
 * Gyro saturation prevention.
75 
 */
76 
// How far from the end of its range a gyro is considered near-saturated.
77 
#define SENSOR_MIN 32
78 
// Other end of the range (calculated)
79 
#define SENSOR_MAX (GYRO_OVERSAMPLING * 1023 - SENSOR_MIN)
80 
// Max. boost to add "virtually" to gyro signal at total saturation.
81 
#define EXTRAPOLATION_LIMIT 2500
82 
// Slope of the boost (calculated)
83 
#define EXTRAPOLATION_SLOPE (EXTRAPOLATION_LIMIT/SENSOR_MIN)
84 
 
85 
/*
86 
 * This value is subtracted from the gyro noise measurement in each iteration,
87 
 * making it return towards zero.
88 
 */
89 
#define GYRO_NOISE_MEASUREMENT_DAMPING 5
90 
 
91 
#define PITCH 0
92 
#define ROLL 1
93 
#define YAW 2
94 
//#define Z 2
95 
/*
96 
 * The values that this module outputs
97 
 * These first 2 exported arrays are zero-offset. The "PID" ones are used
98 
 * in the attitude control as rotation rates. The "ATT" ones are for
99 
 * integration to angles. For the same axis, the PID and ATT variables
100 
 * generally have about the same values. There are just some differences
101 
 * in filtering, and when a gyro becomes near saturated.
102 
 * Maybe this distinction is not really necessary.
103 
 */
104 
extern int16_t gyro_PID[3];
105 
extern int16_t gyro_ATT[3];
106 
extern int16_t gyroD[3];
107 
 
2141 - 108 
#define GYRO_D_WINDOW_LENGTH 16
2108 - 109 
 
110 
extern uint16_t UBat;
111 
extern uint16_t airspeedVelocity;
112 
 
113 
// 1:11 voltage divider, 1024 counts per 3V, and result is divided by 3.
114 
#define UBAT_AT_5V (int16_t)((5.0 * (1.0/11.0)) * 1024 / (3.0 * 3))
115 
extern sensorOffset_t gyroOffset;
116 
extern uint16_t airpressureOffset;
117 
 
118 
/*
119 
 * This is not really for external use - but the ENC-03 gyro modules needs it.
120 
 */
121 
//extern volatile int16_t rawGyroSum[3];
122 
 
123 
/*
124 
 * The acceleration values that this module outputs. They are zero based.
125 
 */
126 
//extern int16_t acc[3];
127 
//extern int16_t filteredAcc[3];
128 
// extern volatile int32_t stronglyFilteredAcc[3];
129 
 
130 
/*
131 
 * Diagnostics: Gyro noise level because of motor vibrations. The variables
132 
 * only really reflect the noise level when the copter stands still but with
133 
 * its motors running.
134 
 */
135 
extern uint16_t gyroNoisePeak[3];
136 
 
137 
/*
138 
 * Air pressure.
139 
 * The sensor has a sensitivity of 45 mV/kPa.
140 
 * An approximate p(h) formula is = p(h[m])[kPa] = p_0 - 11.95 * 10^-3 * h
141 
 * p(h[m])[kPa] = 101.3 - 11.95 * 10^-3 * h
142 
 * 11.95 * 10^-3 * h = 101.3 - p[kPa]
143 
 * h = (101.3 - p[kPa])/0.01195
144 
 * That is: dV = -45 mV * 11.95 * 10^-3 dh = -0.53775 mV / m.
145 
 * That is, with 38.02 * 1.024 / 3 steps per mV: -7 steps / m
146 
 
147 
Display pressures
148 
4165 mV-->1084.7
149 
4090 mV-->1602.4   517.7
150 
3877 mV-->3107.8  1503.4
151 
 
152 
4165 mV-->1419.1
153 
3503 mV-->208.1
154 
Diff.:   1211.0
155 
 
156 
Calculated  Vout = 5V(.009P-0.095) --> 5V .009P = Vout + 5V 0.095 --> P = (Vout + 5V 0.095)/(5V 0.009)
157 
4165 mV = 5V(0.009P-0.095)  P = 103.11 kPa  h = -151.4m
158 
4090 mV = 5V(0.009P-0.095)  P = 101.44 kPa  h = -11.7m   139.7m
159 
3877 mV = 5V(0.009P-0.095)  P = 96.7   kPa  h = 385m     396.7m
160 
 
161 
4165 mV = 5V(0.009P-0.095)  P = 103.11 kPa  h = -151.4m
162 
3503 mV = 5V(0.009P-0.095)  P = 88.4   kPa  h = 384m  Diff: 1079.5m
163 
Pressure at sea level: 101.3 kPa. voltage: 5V * (0.009P-0.095) = 4.0835V
164 
This is OCR2 = 143.15 at 1.5V in --> simple pressure =
165 
*/
166 
 
167 
#define AIRPRESSURE_WINDOW_LENGTH 32
168 
extern uint16_t airspeedVelocity;
169 
 
170 
/*
171 
 * Flag: Interrupt handler has done all A/D conversion and processing.
172 
 */
173 
#define ADC_DATA_READY 1
174 
#define TWI_DATA_READY 2
175 
#define ALL_DATA_READY (ADC_DATA_READY+TWI_DATA_READY)
176 
 
177 
extern volatile uint8_t sensorDataReady;
178 
 
179 
void analog_init(void);
180 
 
181 
/*
182 
 * This is really only for use for the ENC-03 code module, which needs to get the raw value
183 
 * for its calibration. The raw value should not be used for anything else.
184 
 */
2133 - 185 
//int16_t rawGyroValue(uint8_t axis);
2108 - 186 
 
187 
/*
188 
 * Start the conversion cycle. It will stop automatically.
189 
 */
190 
void startAnalogConversionCycle(void);
191 
 
192 
/*
193 
 * Process the sensor data to update the exported variables. Must be called after each measurement cycle and before the data is used.
194 
 */
195 
void analog_update(void);
196 
 
197 
/*
198 
 * Read gyro and acc.meter calibration from EEPROM.
199 
 */
200 
void analog_setNeutral(void);
201 
 
202 
/*
203 
 * Zero-offset gyros and write the calibration data to EEPROM.
204 
 */
205 
void analog_calibrate(void);
206 
 
207 
#endif //_ANALOG_H