| /hardware/qcom/sm8150p/gps/utils/ |
| D | loc_nmea.h | 72 double Z; member
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| D | loc_nmea.cpp | 169 pecef.Z = (r * OMES + plla.alt) * sin(plla.lat); in convert_Lla_to_Ecef()
198 pPZ90.X = deltaX + deltaScale * (pWGS84.X + rotZ * pWGS84.Y - rotY * pWGS84.Z); in convert_WGS84_to_PZ90()
199 pPZ90.Y = deltaY + deltaScale * (pWGS84.Y - rotZ * pWGS84.X + rotX * pWGS84.Z); in convert_WGS84_to_PZ90()
200 pPZ90.Z = deltaZ + deltaScale * (pWGS84.Z + rotY * pWGS84.X - rotX * pWGS84.Y); in convert_WGS84_to_PZ90()
234 r = sqrt(p * p + pecef.Z * pecef.Z); in convert_Ecef_to_Lla()
243 Mu = atan2(pecef.Z * (Ecef1Mf + EcefE2 * EcefA / r), p); in convert_Ecef_to_Lla()
245 if (pecef.Z > 0.0) { in convert_Ecef_to_Lla()
253 Phi = atan2(pecef.Z * Ecef1Mf + EcefE2 * EcefA * Smu * Smu * Smu, in convert_Ecef_to_Lla()
257 plla.alt = p * cos(Phi) + pecef.Z * Sphi - EcefA * EcefA/N; in convert_Ecef_to_Lla()
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| /hardware/qcom/sm7150/gps/utils/ |
| D | loc_nmea.h | 72 double Z; member
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| D | loc_nmea.cpp | 169 pecef.Z = (r * OMES + plla.alt) * sin(plla.lat); in convert_Lla_to_Ecef()
198 pPZ90.X = deltaX + deltaScale * (pWGS84.X + rotZ * pWGS84.Y - rotY * pWGS84.Z); in convert_WGS84_to_PZ90()
199 pPZ90.Y = deltaY + deltaScale * (pWGS84.Y - rotZ * pWGS84.X + rotX * pWGS84.Z); in convert_WGS84_to_PZ90()
200 pPZ90.Z = deltaZ + deltaScale * (pWGS84.Z + rotY * pWGS84.X - rotX * pWGS84.Y); in convert_WGS84_to_PZ90()
234 r = sqrt(p * p + pecef.Z * pecef.Z); in convert_Ecef_to_Lla()
243 Mu = atan2(pecef.Z * (Ecef1Mf + EcefE2 * EcefA / r), p); in convert_Ecef_to_Lla()
245 if (pecef.Z > 0.0) { in convert_Ecef_to_Lla()
253 Phi = atan2(pecef.Z * Ecef1Mf + EcefE2 * EcefA * Smu * Smu * Smu, in convert_Ecef_to_Lla()
257 plla.alt = p * cos(Phi) + pecef.Z * Sphi - EcefA * EcefA/N; in convert_Ecef_to_Lla()
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| /hardware/qcom/sm8150/gps/utils/ |
| D | loc_nmea.h | 72 double Z; member
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| D | loc_nmea.cpp | 169 pecef.Z = (r * OMES + plla.alt) * sin(plla.lat); in convert_Lla_to_Ecef()
198 pPZ90.X = deltaX + deltaScale * (pWGS84.X + rotZ * pWGS84.Y - rotY * pWGS84.Z); in convert_WGS84_to_PZ90()
199 pPZ90.Y = deltaY + deltaScale * (pWGS84.Y - rotZ * pWGS84.X + rotX * pWGS84.Z); in convert_WGS84_to_PZ90()
200 pPZ90.Z = deltaZ + deltaScale * (pWGS84.Z + rotY * pWGS84.X - rotX * pWGS84.Y); in convert_WGS84_to_PZ90()
234 r = sqrt(p * p + pecef.Z * pecef.Z); in convert_Ecef_to_Lla()
243 Mu = atan2(pecef.Z * (Ecef1Mf + EcefE2 * EcefA / r), p); in convert_Ecef_to_Lla()
245 if (pecef.Z > 0.0) { in convert_Ecef_to_Lla()
253 Phi = atan2(pecef.Z * Ecef1Mf + EcefE2 * EcefA * Smu * Smu * Smu, in convert_Ecef_to_Lla()
257 plla.alt = p * cos(Phi) + pecef.Z * Sphi - EcefA * EcefA/N; in convert_Ecef_to_Lla()
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| /hardware/interfaces/gnss/2.1/ |
| D | IGnssAntennaInfoCallback.hal | 69 * angle, phi, is defined with respect to the Z axis of the Android Sensor
103 * angle, phi, is defined with respect to the Z axis of the Android Sensor
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| /hardware/interfaces/automotive/evs/1.1/ |
| D | types.hal | 261 * when viewing the car from top on the +Z axis side:
272 * Rotation = + 90 degrees around Z axis = (0.7071, 0, 0, 0.7071) as a unit quaternion.
294 * The +Y axis points along the center of the beam spread the X axis to the right and the Z
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| /hardware/interfaces/renderscript/1.0/ |
| D | IContext.hal | 229 * @param z Z position of the first element in the Allocation to be
276 * @param zoff Z offset of the region to update in this Allocation
354 * @param z Z position of the first element in the Allocation to be read
408 * @param zoff Z offset of the region to copy in this array
493 * @param dstZoff Z offset of the region to update
501 * @param srcZoff Source Z offset of the region in the souce Allocation
550 * @param z Z position
630 * If Type is 1D, Y and Z must be 0. If Type is 2D, Z must be 0.
635 * @param dimZ Z dimension
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| /hardware/interfaces/gnss/2.0/ |
| D | IGnssMeasurementCallback.hal | 423 * Value "W" represents GPS L1 Z-tracking, GPS L2 Z-tracking.
432 * Value "Z" represents GALILEO E1 (A+B+C), GALILEO E6 (A+B+C), QZSS L1-SAIF.
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| /hardware/interfaces/sensors/1.0/ |
| D | types.hal | 144 * field in the X, Y and Z axis.
170 * around the X, Y and Z axis.
300 * around the X, Y and Z axis.
510 * Moving the device to an orientation where the Z axis is vertical (either
1034 * - the device Z axis and sensor's local Z axis are equivalent
1036 * system from the positive Z direction, the device coordinate frame is
1037 * to be rotated 90 degrees counter-clockwise about the Z axis to align
1044 * 2.5mm in the negative Z direction.
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| /hardware/interfaces/automotive/sv/1.0/ |
| D | types.hal | 98 * +Z as up direction.
113 * Rotation = + 90 degrees around Z axis = (0.7071, 0, 0, 0.7071) as a unit quaternion.
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| /hardware/interfaces/input/common/1.0/ |
| D | types.hal | 169 * Axis constant: Z axis of a motion event.
171 * - For a joystick, reports the absolute Z position of the joystick.
176 Z = 11,
192 * Axis constant: Z Rotation axis of a motion event.
194 * - For a joystick, reports the absolute rotation angle about the Z axis.
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| /hardware/interfaces/automotive/can/1.0/ |
| D | ICanController.hal | 91 * (a-z, A-Z, 0-9, '_'), at least 1 and at most 32 characters long.
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| /hardware/interfaces/graphics/composer/2.1/ |
| D | IComposerClient.hal | 1092 * Sets the desired Z order (height) of the given layer. A layer with a
1093 * greater Z value occludes a layer with a lesser Z value.
1095 * @param z is the new Z order.
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| /hardware/interfaces/gnss/1.0/ |
| D | IGnssMeasurementCallback.hal | 181 * and the true GPS time since 0000Z, January 6, 1980, in nanoseconds.
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| /hardware/interfaces/wifi/1.0/ |
| D | types.hal | 999 * values (A-Z, a-z, 0-9), the hyphen ('-'), and the period ('.'). All valid multi-byte UTF-8
1992 /** Following element for configuring the Z subelement. */
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| /hardware/interfaces/automotive/vehicle/2.0/ |
| D | types.hal | 1546 * Mirror Z Position
1560 * Mirror Z Move
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