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1 /*
2  * Copyright (C) 2011 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 #include "SensorDevice.h"
18 #include "SensorFusion.h"
19 #include "SensorService.h"
20 
21 namespace android {
22 // ---------------------------------------------------------------------------
23 
ANDROID_SINGLETON_STATIC_INSTANCE(SensorFusion)24 ANDROID_SINGLETON_STATIC_INSTANCE(SensorFusion)
25 
26 SensorFusion::SensorFusion()
27     : mSensorDevice(SensorDevice::getInstance()),
28       mAttitude(mAttitudes[FUSION_9AXIS]),
29       mGyroTime(0), mAccTime(0)
30 {
31     sensor_t const* list;
32     Sensor uncalibratedGyro;
33     ssize_t count = mSensorDevice.getSensorList(&list);
34 
35     mEnabled[FUSION_9AXIS] = false;
36     mEnabled[FUSION_NOMAG] = false;
37     mEnabled[FUSION_NOGYRO] = false;
38 
39     if (count > 0) {
40         for (size_t i=0 ; i<size_t(count) ; i++) {
41             if (list[i].type == SENSOR_TYPE_ACCELEROMETER) {
42                 mAcc = Sensor(list + i);
43             }
44             if (list[i].type == SENSOR_TYPE_MAGNETIC_FIELD) {
45                 mMag = Sensor(list + i);
46             }
47             if (list[i].type == SENSOR_TYPE_GYROSCOPE) {
48                 mGyro = Sensor(list + i);
49             }
50             if (list[i].type == SENSOR_TYPE_GYROSCOPE_UNCALIBRATED) {
51                 uncalibratedGyro = Sensor(list + i);
52             }
53         }
54 
55         // Use the uncalibrated gyroscope for sensor fusion when available
56         if (uncalibratedGyro.getType() == SENSOR_TYPE_GYROSCOPE_UNCALIBRATED) {
57             mGyro = uncalibratedGyro;
58         }
59 
60         // 200 Hz for gyro events is a good compromise between precision
61         // and power/cpu usage.
62         mEstimatedGyroRate = 200;
63         mTargetDelayNs = 1000000000LL/mEstimatedGyroRate;
64 
65         for (int i = 0; i<NUM_FUSION_MODE; ++i) {
66             mFusions[i].init(i);
67         }
68     }
69 }
70 
process(const sensors_event_t & event)71 void SensorFusion::process(const sensors_event_t& event) {
72 
73     if (event.type == mGyro.getType()) {
74         float dT;
75         if ( event.timestamp - mGyroTime> 0 &&
76              event.timestamp - mGyroTime< (int64_t)(5e7) ) { //0.05sec
77 
78             dT = (event.timestamp - mGyroTime) / 1000000000.0f;
79             // here we estimate the gyro rate (useful for debugging)
80             const float freq = 1 / dT;
81             if (freq >= 100 && freq<1000) { // filter values obviously wrong
82                 const float alpha = 1 / (1 + dT); // 1s time-constant
83                 mEstimatedGyroRate = freq + (mEstimatedGyroRate - freq)*alpha;
84             }
85 
86             const vec3_t gyro(event.data);
87             for (int i = 0; i<NUM_FUSION_MODE; ++i) {
88                 if (mEnabled[i]) {
89                     // fusion in no gyro mode will ignore
90                     mFusions[i].handleGyro(gyro, dT);
91                 }
92             }
93         }
94         mGyroTime = event.timestamp;
95     } else if (event.type == SENSOR_TYPE_MAGNETIC_FIELD) {
96         const vec3_t mag(event.data);
97         for (int i = 0; i<NUM_FUSION_MODE; ++i) {
98             if (mEnabled[i]) {
99                 mFusions[i].handleMag(mag);// fusion in no mag mode will ignore
100             }
101         }
102     } else if (event.type == SENSOR_TYPE_ACCELEROMETER) {
103         float dT;
104         if ( event.timestamp - mAccTime> 0 &&
105              event.timestamp - mAccTime< (int64_t)(1e8) ) { //0.1sec
106             dT = (event.timestamp - mAccTime) / 1000000000.0f;
107 
108             const vec3_t acc(event.data);
109             for (int i = 0; i<NUM_FUSION_MODE; ++i) {
110                 if (mEnabled[i]) {
111                     mFusions[i].handleAcc(acc, dT);
112                     mAttitudes[i] = mFusions[i].getAttitude();
113                 }
114             }
115         }
116         mAccTime = event.timestamp;
117     }
118 }
119 
min(T a,T b)120 template <typename T> inline T min(T a, T b) { return a<b ? a : b; }
max(T a,T b)121 template <typename T> inline T max(T a, T b) { return a>b ? a : b; }
122 
activate(int mode,void * ident,bool enabled)123 status_t SensorFusion::activate(int mode, void* ident, bool enabled) {
124 
125     ALOGD_IF(DEBUG_CONNECTIONS,
126             "SensorFusion::activate(mode=%d, ident=%p, enabled=%d)",
127             mode, ident, enabled);
128 
129     const ssize_t idx = mClients[mode].indexOf(ident);
130     if (enabled) {
131         if (idx < 0) {
132             mClients[mode].add(ident);
133         }
134     } else {
135         if (idx >= 0) {
136             mClients[mode].removeItemsAt(idx);
137         }
138     }
139 
140     const bool newState = mClients[mode].size() != 0;
141     if (newState != mEnabled[mode]) {
142         mEnabled[mode] = newState;
143         if (newState) {
144             mFusions[mode].init(mode);
145         }
146     }
147 
148     mSensorDevice.activate(ident, mAcc.getHandle(), enabled);
149     if (mode != FUSION_NOMAG) {
150         mSensorDevice.activate(ident, mMag.getHandle(), enabled);
151     }
152     if (mode != FUSION_NOGYRO) {
153         mSensorDevice.activate(ident, mGyro.getHandle(), enabled);
154     }
155 
156     return NO_ERROR;
157 }
158 
setDelay(int mode,void * ident,int64_t ns)159 status_t SensorFusion::setDelay(int mode, void* ident, int64_t ns) {
160     // Call batch with timeout zero instead of setDelay().
161     if (ns > (int64_t)5e7) {
162         ns = (int64_t)(5e7);
163     }
164     mSensorDevice.batch(ident, mAcc.getHandle(), 0, ns, 0);
165     if (mode != FUSION_NOMAG) {
166         mSensorDevice.batch(ident, mMag.getHandle(), 0, ms2ns(20), 0);
167     }
168     if (mode != FUSION_NOGYRO) {
169         mSensorDevice.batch(ident, mGyro.getHandle(), 0, mTargetDelayNs, 0);
170     }
171     return NO_ERROR;
172 }
173 
174 
getPowerUsage(int mode) const175 float SensorFusion::getPowerUsage(int mode) const {
176     float power =   mAcc.getPowerUsage() +
177                     ((mode != FUSION_NOMAG) ? mMag.getPowerUsage() : 0) +
178                     ((mode != FUSION_NOGYRO) ? mGyro.getPowerUsage() : 0);
179     return power;
180 }
181 
getMinDelay() const182 int32_t SensorFusion::getMinDelay() const {
183     return mAcc.getMinDelay();
184 }
185 
dump(String8 & result)186 void SensorFusion::dump(String8& result) {
187     const Fusion& fusion_9axis(mFusions[FUSION_9AXIS]);
188     result.appendFormat("9-axis fusion %s (%zd clients), gyro-rate=%7.2fHz, "
189             "q=< %g, %g, %g, %g > (%g), "
190             "b=< %g, %g, %g >\n",
191             mEnabled[FUSION_9AXIS] ? "enabled" : "disabled",
192             mClients[FUSION_9AXIS].size(),
193             mEstimatedGyroRate,
194             fusion_9axis.getAttitude().x,
195             fusion_9axis.getAttitude().y,
196             fusion_9axis.getAttitude().z,
197             fusion_9axis.getAttitude().w,
198             length(fusion_9axis.getAttitude()),
199             fusion_9axis.getBias().x,
200             fusion_9axis.getBias().y,
201             fusion_9axis.getBias().z);
202 
203     const Fusion& fusion_nomag(mFusions[FUSION_NOMAG]);
204     result.appendFormat("game fusion(no mag) %s (%zd clients), "
205             "gyro-rate=%7.2fHz, "
206             "q=< %g, %g, %g, %g > (%g), "
207             "b=< %g, %g, %g >\n",
208             mEnabled[FUSION_NOMAG] ? "enabled" : "disabled",
209             mClients[FUSION_NOMAG].size(),
210             mEstimatedGyroRate,
211             fusion_nomag.getAttitude().x,
212             fusion_nomag.getAttitude().y,
213             fusion_nomag.getAttitude().z,
214             fusion_nomag.getAttitude().w,
215             length(fusion_nomag.getAttitude()),
216             fusion_nomag.getBias().x,
217             fusion_nomag.getBias().y,
218             fusion_nomag.getBias().z);
219 
220     const Fusion& fusion_nogyro(mFusions[FUSION_NOGYRO]);
221     result.appendFormat("geomag fusion (no gyro) %s (%zd clients), "
222             "gyro-rate=%7.2fHz, "
223             "q=< %g, %g, %g, %g > (%g), "
224             "b=< %g, %g, %g >\n",
225             mEnabled[FUSION_NOGYRO] ? "enabled" : "disabled",
226             mClients[FUSION_NOGYRO].size(),
227             mEstimatedGyroRate,
228             fusion_nogyro.getAttitude().x,
229             fusion_nogyro.getAttitude().y,
230             fusion_nogyro.getAttitude().z,
231             fusion_nogyro.getAttitude().w,
232             length(fusion_nogyro.getAttitude()),
233             fusion_nogyro.getBias().x,
234             fusion_nogyro.getBias().y,
235             fusion_nogyro.getBias().z);
236 }
237 
238 // ---------------------------------------------------------------------------
239 }; // namespace android
240