2 * Copyright © 2019 Keith Packard <keithp@keithp.com>
4 * This program is free software; you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation; either version 2 of the License, or
7 * (at your option) any later version.
9 * This program is distributed in the hope that it will be useful, but
10 * WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
12 * General Public License for more details.
14 * You should have received a copy of the GNU General Public License along
15 * with this program; if not, write to the Free Software Foundation, Inc.,
16 * 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
20 #include <ao_bmx160.h>
23 static uint8_t ao_bmx160_configured;
25 #define ao_bmx160_spi_get() ao_spi_get(AO_BMX160_SPI_BUS, AO_SPI_SPEED_8MHz)
26 #define ao_bmx160_spi_put() ao_spi_put(AO_BMX160_SPI_BUS)
28 #define ao_bmx160_spi_start() ao_spi_set_cs(AO_BMX160_SPI_CS_PORT, \
29 (1 << AO_BMX160_SPI_CS_PIN))
31 #define ao_bmx160_spi_end() ao_spi_clr_cs(AO_BMX160_SPI_CS_PORT, \
32 (1 << AO_BMX160_SPI_CS_PIN))
35 _ao_bmx160_reg_write(uint8_t addr, uint8_t value)
37 uint8_t d[2] = { addr, value };
38 ao_bmx160_spi_start();
39 ao_spi_send(d, 2, AO_BMX160_SPI_BUS);
44 _ao_bmx160_read(uint8_t addr, void *data, uint8_t len)
47 ao_bmx160_spi_start();
48 ao_spi_send(&addr, 1, AO_BMX160_SPI_BUS);
49 ao_spi_recv(data, len, AO_BMX160_SPI_BUS);
54 _ao_bmx160_reg_read(uint8_t addr)
58 ao_bmx160_spi_start();
59 ao_spi_send(&addr, 1, AO_BMX160_SPI_BUS);
60 ao_spi_recv(&value, 1, AO_BMX160_SPI_BUS);
66 _ao_bmx160_cmd(uint8_t cmd)
68 _ao_bmx160_reg_write(BMX160_CMD, cmd);
69 ao_delay(AO_MS_TO_TICKS(100));
73 _ao_bmx160_mag_setup(void)
75 _ao_bmx160_reg_write(BMX160_MAG_IF_0, 0x80);
79 _ao_bmm150_wait_manual(void)
81 while (_ao_bmx160_reg_read(BMX160_STATUS) & (1 << BMX160_STATUS_MAG_MAN_OP))
86 _ao_bmm150_reg_write(uint8_t addr, uint8_t data)
88 _ao_bmx160_reg_write(BMX160_MAG_IF_3, data);
89 _ao_bmx160_reg_write(BMX160_MAG_IF_2, addr);
90 _ao_bmm150_wait_manual();
95 _ao_bmm150_reg_read(uint8_t addr)
97 _ao_bmx160_reg_write(BMX160_MAG_IF_1, addr);
98 _ao_bmm150_wait_manual();
99 return _ao_bmx160_reg_read(BMX160_DATA_0);
104 _ao_bmx160_sample(struct ao_bmx160_sample *sample)
106 _ao_bmx160_read(BMX160_MAG_X_0_7, sample, sizeof (*sample));
107 #if __BYTE_ORDER != __LITTLE_ENDIAN
108 int i = sizeof (*sample) / 2;
109 uint16_t *d = (uint16_t *) sample;
114 *d++ = (t >> 8) | (t << 8);
119 #define G 981 /* in cm/s² */
122 static int16_t /* cm/s² */
123 ao_bmx160_accel(int16_t v)
125 return (int16_t) ((v * (int32_t) (16.0 * 980.665 + 0.5)) / 32767);
128 static int16_t /* deg*10/s */
129 ao_bmx160_gyro(int16_t v)
131 return (int16_t) ((v * (int32_t) 20000) / 32767);
135 ao_bmx160_accel_check(int16_t normal, int16_t test)
137 int16_t diff = test - normal;
139 if (diff < BMX160_ST_ACCEL(16) / 4) {
142 if (diff > BMX160_ST_ACCEL(16) * 4) {
149 ao_bmx160_gyro_check(int16_t normal, int16_t test)
151 int16_t diff = test - normal;
155 if (diff < BMX160_ST_GYRO(2000) / 4) {
158 if (diff > BMX160_ST_GYRO(2000) * 4) {
166 _ao_bmx160_wait_alive(void)
170 /* Wait for the chip to wake up */
171 for (i = 0; i < 30; i++) {
172 ao_delay(AO_MS_TO_TICKS(100));
173 if (_ao_bmx160_reg_read(BMX160_CHIPID) == BMX160_CHIPID_BMX160)
177 ao_panic(AO_PANIC_SELF_TEST_BMX160);
184 _ao_bmx160_setup(void)
188 if (ao_bmx160_configured)
191 /* Make sure the chip is responding */
192 _ao_bmx160_wait_alive();
195 // _ao_bmx160_cmd(BMX160_CMD_SOFTRESET);
198 _ao_bmx160_reg_write(BMX160_NV_CONF, 1 << BMX160_NV_CONF_SPI_EN);
200 /* Enable acc and gyr
203 _ao_bmx160_cmd(BMX160_CMD_ACC_SET_PMU_MODE(BMX160_PMU_STATUS_ACC_PMU_STATUS_NORMAL));
205 _ao_bmx160_cmd(BMX160_CMD_GYR_SET_PMU_MODE(BMX160_PMU_STATUS_GYR_PMU_STATUS_NORMAL));
207 /* Configure accelerometer:
209 * undersampling disabled
211 * 200Hz sampling rate
214 * This yields a 3dB cutoff frequency of 80Hz
216 _ao_bmx160_reg_write(BMX160_ACC_CONF,
217 (0 << BMX160_ACC_CONF_ACC_US) |
218 (BMX160_ACC_CONF_ACC_BWP_NORMAL << BMX160_ACC_CONF_ACC_BWP) |
219 (BMX160_ACC_CONF_ACC_ODR_200 << BMX160_ACC_CONF_ACC_ODR));
220 _ao_bmx160_reg_write(BMX160_ACC_RANGE,
221 BMX160_ACC_RANGE_16G);
222 for (r = 0x4; r <= 0x17; r++)
223 (void) _ao_bmx160_reg_read(r);
228 * 200Hz sampling rate
232 _ao_bmx160_reg_write(BMX160_GYR_CONF,
233 (BMX160_GYR_CONF_GYR_BWP_NORMAL << BMX160_GYR_CONF_GYR_BWP) |
234 (BMX160_GYR_CONF_GYR_ODR_200 << BMX160_GYR_CONF_GYR_ODR));
235 _ao_bmx160_reg_write(BMX160_GYR_RANGE,
236 BMX160_GYR_RANGE_2000);
239 /* Configure magnetometer:
245 _ao_bmx160_cmd(BMX160_CMD_MAG_IF_SET_PMU_MODE(BMX160_PMU_STATUS_MAG_IF_PMU_STATUS_NORMAL));
247 /* Enter setup mode */
248 _ao_bmx160_mag_setup();
250 /* Place in suspend mode to reboot the chip */
251 _ao_bmm150_reg_write(BMM150_POWER_MODE,
252 (0 << BMM150_POWER_MODE_POWER_CONTROL));
255 _ao_bmm150_reg_write(BMM150_POWER_MODE,
256 (1 << BMM150_POWER_MODE_POWER_CONTROL));
258 /* Set data rate and place in sleep mode */
259 _ao_bmm150_reg_write(BMM150_CONTROL,
260 (BMM150_CONTROL_DATA_RATE_30 << BMM150_CONTROL_DATA_RATE) |
261 (BMM150_CONTROL_OP_MODE_SLEEP << BMM150_CONTROL_OP_MODE));
263 /* enable all axes (should already be enabled) */
264 _ao_bmm150_reg_write(BMM150_INT_CONF,
265 (0 << BMM150_INT_CONF_X_DISABLE) |
266 (0 << BMM150_INT_CONF_Y_DISABLE) |
267 (0 << BMM150_INT_CONF_Z_DISABLE));
269 /* Set repetition values (?) */
270 _ao_bmm150_reg_write(BMM150_REPXY, BMM150_REPXY_VALUE(9));
271 _ao_bmm150_reg_write(BMM150_REPZ, BMM150_REPZ_VALUE(15));
273 /* To get data out of the magnetometer, set the control op mode to 'forced', then read
274 * from the data registers
276 _ao_bmx160_reg_write(BMX160_MAG_IF_3, (BMM150_CONTROL_OP_MODE_FORCED << BMM150_CONTROL_OP_MODE));
277 _ao_bmx160_reg_write(BMX160_MAG_IF_2, BMM150_CONTROL);
278 _ao_bmx160_reg_write(BMX160_MAG_IF_1, BMM150_DATA_X_0_4);
280 /* Set data rate to 200Hz */
281 _ao_bmx160_reg_write(BMX160_MAG_CONF,
282 (BMX160_MAG_CONF_MAG_ODR_200 << BMX160_MAG_CONF_MAG_ODR));
284 /* Put magnetometer interface back into 'normal mode'
286 _ao_bmx160_reg_write(BMX160_MAG_IF_0,
287 (0 << BMX160_MAG_IF_0_MAG_MANUAL_EN) |
288 (0 << BMX160_MAG_IF_0_MAG_OFFSET) |
289 (0 << BMX160_MAG_IF_0_MAG_RD_BURST));
291 ao_bmx160_configured = 1;
294 struct ao_bmx160_sample ao_bmx160_current;
299 struct ao_bmx160_sample sample;
301 /* ao_bmx160_init already grabbed the SPI bus and mutex */
307 _ao_bmx160_sample(&sample);
309 ao_arch_block_interrupts();
310 ao_bmx160_current = sample;
311 AO_DATA_PRESENT(AO_DATA_BMX160);
313 ao_arch_release_interrupts();
317 static struct ao_task ao_bmx160_task;
323 uint8_t acc_conf = _ao_bmx160_reg_read(BMX160_ACC_CONF);
324 uint8_t acc_range = _ao_bmx160_reg_read(BMX160_ACC_RANGE);
325 uint8_t gyr_conf = _ao_bmx160_reg_read(BMX160_GYR_CONF);
326 uint8_t gyr_range = _ao_bmx160_reg_read(BMX160_GYR_RANGE);
327 uint8_t mag_conf = _ao_bmx160_reg_read(BMX160_MAG_CONF);
328 uint8_t status = _ao_bmx160_reg_read(BMX160_STATUS);
329 uint8_t pmu_status = _ao_bmx160_reg_read(BMX160_PMU_STATUS);
330 uint8_t acc_x_lo = _ao_bmx160_reg_read(BMX160_ACCEL_X_0_7);
331 uint8_t acc_x_hi = _ao_bmx160_reg_read(BMX160_ACCEL_X_8_15);
334 printf("ACC_CONF %02x ACC_RANGE %02x GYR_CONF %02x GYR_RANGE %02x MAG_CONF %02x\n",
335 acc_conf, acc_range, gyr_conf, gyr_range, mag_conf);
337 printf("STATUS %02x PMU_STATUS %02x ACCEL_X_0_7 %02x ACCEL_X_8_15 %02x\n",
338 status, pmu_status, acc_x_lo, acc_x_hi);
340 printf ("Accel: %7d %7d %7d Gyro: %7d %7d %7d Mag: %7d %7d %7d\n",
341 ao_bmx160_current.acc_x,
342 ao_bmx160_current.acc_y,
343 ao_bmx160_current.acc_z,
344 ao_bmx160_current.gyr_x,
345 ao_bmx160_current.gyr_y,
346 ao_bmx160_current.gyr_z,
347 ao_bmx160_current.mag_x,
348 ao_bmx160_current.mag_y,
349 ao_bmx160_current.mag_z);
362 if (ao_cmd_status != ao_cmd_success)
365 val = _ao_bmx160_reg_read(addr);
367 printf("Addr %02x val %02x\n", addr, val);
371 ao_bmx160_write(void)
377 if (ao_cmd_status != ao_cmd_success)
380 if (ao_cmd_status != ao_cmd_success)
382 printf("Addr %02x val %02x\n", addr, val);
384 _ao_bmx160_reg_write(addr, val);
395 if (ao_cmd_status != ao_cmd_success)
398 val = _ao_bmm150_reg_read(addr);
400 printf("Addr %02x val %02x\n", addr, val);
404 ao_bmm150_write(void)
410 if (ao_cmd_status != ao_cmd_success)
413 if (ao_cmd_status != ao_cmd_success)
415 printf("Addr %02x val %02x\n", addr, val);
417 _ao_bmm150_reg_write(addr, val);
421 #endif /* BMX160_TEST */
423 static const struct ao_cmds ao_bmx160_cmds[] = {
424 { ao_bmx160_show, "I\0Show BMX160 status" },
426 { ao_bmx160_read, "R <addr>\0Read BMX160 register" },
427 { ao_bmx160_write, "W <addr> <val>\0Write BMX160 register" },
428 { ao_bmm150_read, "M <addr>\0Read BMM150 register" },
429 { ao_bmm150_write, "N <addr> <val>\0Write BMM150 register" },
437 ao_add_task(&ao_bmx160_task, ao_bmx160, "bmx160");
439 ao_spi_init_cs(AO_BMX160_SPI_CS_PORT, (1 << AO_BMX160_SPI_CS_PIN));
441 /* Pretend to be the bmx160 task. Grab the SPI bus right away and
442 * hold it for the task so that nothing else uses the SPI bus before
443 * we get the I2C mode disabled in the chip
446 ao_cur_task = &ao_bmx160_task;
449 ao_cmd_register(&ao_bmx160_cmds[0]);