| /external/opencv/cvaux/src/ |
| cvvecfacetracking.cpp | 92 int Energy(const CvTrackingRect& prev)
226 void Energy();
239 Energy();
245 Energy();
252 Energy();
259 Energy();
393 void CvFaceElement::Energy()
420 // energy
421 pRect->Energy(m_trPrev);
424 }//void CvFaceElement::Energy()
792 int energy = 0; local
837 int energy = ppNew[element[0]]->iEnergy + ppNew[element[1]]->iEnergy + local
[all...] |
| /external/webrtc/src/modules/audio_processing/ns/ |
| defines.h | 52 #define B_LIM (float)0.5 // threshold in final energy gain factor calculation
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| /frameworks/av/media/libstagefright/codecs/aacenc/src/ |
| band_nrg.c | 19 Content: Band/Line energy calculations functions
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| /frameworks/av/media/libstagefright/codecs/amrnb/enc/src/ |
| qgain475.cpp | 413 Word16 qua_ener_MR122; // o : quantized energy error, MR122 version Q10
414 Word16 qua_ener; // o : quantized energy error, Q10
490 Word16 qua_ener_MR122; /* o : quantized energy error, MR122 version Q10 */
491 Word16 qua_ener; /* o : quantized energy error, Q10 */
799 sf0_exp_coeff = energy coeff. (exponent part) (Word16)
800 sf0_frac_coeff = energy coeff. ((fraction part) (Word16)
801 sf0_exp_target_en = exponent of target energy (Word16)
802 sf0_frac_target_en = fraction of target energy (Word16)
806 sf1_exp_coeff = energy coeff. (exponent part) (Word16)
807 sf1_frac_coeff = energy coeff. (fraction part) (Word16
[all...] |
| qgain795.h | 113 Word16 exp_coeff[], /* i : energy coefficients (5), Q0 */
115 Word16 exp_code_en, /* i : innovation energy (exponent), Q0 */
116 Word16 frac_code_en, /* i : innovation energy (fraction), Q15 */
125 Word16 *qua_ener_MR122, /* o : quantized energy error, Q10 */
127 Word16 *qua_ener, /* o : quantized energy error, Q10 */
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| qua_gain.cpp | 125 Word16 frac_coeff -- Word16 Array -- energy coeff. (5), fraction part, Q15
126 Word16 exp_coeff -- Word16 Array -- energy coeff. (5), exponent part, Q0
135 Word16 *qua_ener_MR122 -- Pointer to Word16 -- quantized energy error, Q10
137 Word16 *qua_ener -- Pointer to Word16 -- quantized energy error, Q10
197 Word16 frac_coeff[], /* i : energy coeff. (5), fraction part, Q15 */
198 Word16 exp_coeff[], /* i : energy coeff. (5), exponent part, Q0 */
204 Word16 *qua_ener_MR122, /* o : quantized energy error, Q10 */
206 Word16 *qua_ener, /* o : quantized energy error, Q10 */
260 * The error energy (sum) to be minimized consists of five terms, t[0..4].
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| /external/aac/libAACenc/src/ |
| block_switch.cpp | 127 /* minimum energy for attacks */
128 static const FIXP_DBL minAttackNrg = (FL2FXCONST_DBL(1e+6f*NORM_PCM_ENERGY)>>BLOCK_SWITCH_ENERGY_SHIFT); /* minimum energy for attacks */
141 /* minimum energy for attacks */
142 static const FIXP_DBL minAttackNrg = (FL2FXCONST_DBL(1e+6f*NORM_PCM_ENERGY)>>BLOCK_SWITCH_ENERGY_SHIFT); /* minimum energy for attacks */
241 /* Save current window energy as last window energy */
330 /* For coherency, change FDKaacEnc_GetWindowEnergy() to calcluate the energy for a block switching analysis windows,
332 is used for a comparision of the max energy of left/right channel. */
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| /external/aac/libSBRenc/src/ |
| invf_est.cpp | 190 FIXP_DBL *nrgVector, /*!< Energy vector. */
219 /* The original, the sbr signal and the total energy */
373 /* If energy is zero then we will get different results for different word lengths. */
374 nrg = (fMultDiv2(FL2FXCONST_DBL(2.f*0.375f), (FIXP_DBL)(CalcLdData(detectorValues->avgNrg+(FIXP_DBL)1) + FL2FXCONST_DBL(0.0625f) + FL2FXCONST_DBL(0.6875f)))) << 0; /* scaled by 1/2^8; 2^44 -> qmf energy scale */
400 /* Compensate for low energy.*/
412 the covariance method. THe ratio between the energy of the predicted
413 signal and the energy of the non-predictable signal is calcualted.
422 FIXP_DBL *nrgVector, /*!< The energy vector. */
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| /external/webrtc/src/modules/audio_processing/agc/ |
| digital_agc.c | 699 // high pass filter and compute energy
736 // energy level (range {-32..30}) (Q10)
747 // update short-term estimate of mean energy level (Q10)
751 // update short-term estimate of variance in energy level (Q8)
756 // update short-term estimate of standard deviation in energy level (Q10)
761 // update long-term estimate of mean energy level (Q10)
766 // update long-term estimate of variance in energy level (Q8)
772 // update long-term estimate of standard deviation in energy level (Q10)
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| /frameworks/base/docs/html/training/efficient-downloads/ |
| efficient-network-access.jd | 38 <p>A fully active wireless radio consumes significant power, so it transitions between different energy states in order to conserve power when not in use, while attempting to minimize latency associated with "powering up" the radio when it's required.</p>
40 <p>The state machine for a typical 3G network radio consists of three energy states:
43 <li><b>Standby</b>: The minimal energy state during which no network connection is active or required.</li>
48 <p>To minimize latency, the state machine uses a delay to postpone the transition to lower energy states. Figure 1 uses AT&T's timings for a typical 3G radio.</p>
57 <p>This approach is particularly effective for typical web browsing as it prevents unwelcome latency while users browse the web. The relatively low tail-time also ensures that once a browsing session has finished, the radio can move to a lower energy state.</p>
63 <p>Every time you create a new network connection, the radio transitions to the full power state. In the case of the typical 3G radio state machine described above, it will remain at full power for the duration of your transfer—plus an additional 5 seconds of tail time—followed by 12 seconds at the low energy state. So for a typical 3G device, every data transfer session will cause the radio to draw energy for almost 20 seconds.</p>
104 <p>Using this approach, the radio will be forced to remain active for the majority of users' news-reading session as they scroll headlines, change categories, and read articles. Not only that, but the constant switching between energy states will result in significant latency when switching categories or reading articles.</p>
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| /frameworks/base/media/mca/filterpacks/java/android/filterpacks/imageproc/ |
| GrainFilter.java | 90 " float energy = 0.33333 * color.r + 0.33333 * color.g + 0.33333 * color.b;\n" +
91 " float mask = (1.0 - sqrt(energy));\n" +
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| /frameworks/wilhelm/src/itf/ |
| IAndroidEffectSend.c | 42 // the initial send level set here is the total energy on the aux bus,
163 // the send level set here is the total energy on the aux bus, so it must take
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| /gdk/samples/PhotoEditor/jni/ |
| grain.cpp | 158 // energy_mask is used to constrain the noise according to the energy
160 // The energy level (from 0 to 765) is square-rooted and should in the
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| /frameworks/av/media/libstagefright/codecs/amrwbenc/src/ |
| q_gain2.c | 22 * MA prediction is performed on the innovation energy (in dB with mean *
53 /* 4nd order quantizer energy predictor (init to -14.0 in Q10) */
171 * Find energy of code and compute: *
173 * L_tmp = MEAN_ENER - 10log10(energy of code/ L_subfr) *
174 * = MEAN_ENER - 3.0103*log2(energy of code/ L_subfr) *
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| /external/aac/libAACdec/src/ |
| rvlcconceal.cpp | 104 - reference value noise energy
179 - reference value noise energy
258 intensity data and noise energy seperately.
260 output: Concealed scalefactor, noise energy and intensity data between conceal_min and
391 and noise energy seperately.
393 output: Concealed scalefactor, noise energy and intensity data between conceal_min and
525 must be applied to scalefactors, intensity data and noise energy seperately.
527 output: Concealed scalefactor, noise energy and intensity data
537 int sumNrgFwd,sumNrgBwd; /* sum of noise energy data forward/backward */
629 scalefactor (intensity data, noise energy) in the current frame. Otherwise set
[all...] |
| /external/webrtc/src/modules/audio_processing/aec/ |
| aec_core.c | 878 // Filter energy
894 // Measure energy in each filter partition to determine delay.
1343 float energy = (in[0][0] * in[0][0]) \/ 2; local
[all...] |
| /external/bluetooth/bluez/src/ |
| main.conf | 59 # Enable Low Energy support if the dongle supports. Default is false.
|
| /external/qemu/distrib/sdl-1.2.12/src/video/xbios/ |
| SDL_xbios_centscreen.h | 62 unsigned short eco2; /* energy star screen saver delay */
|
| /external/valgrind/main/ |
| AUTHORS | 76 of Energy's Advanced Simulation & Computing (ASC) Program.
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| /external/valgrind/main/VEX/priv/ |
| ir_match.h | 30 Neither the names of the U.S. Department of Energy nor the
|
| ir_opt.h | 30 Neither the names of the U.S. Department of Energy nor the
|
| main_globals.c | 30 Neither the names of the U.S. Department of Energy nor the
|
| main_globals.h | 30 Neither the names of the U.S. Department of Energy nor the
|
| /external/valgrind/main/coregrind/m_debuginfo/ |
| priv_readdwarf3.h | 31 Neither the names of the U.S. Department of Energy nor the
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| /external/webkit/Tools/android/flex-2.5.4a/ |
| ccl.c | 12 * Department of Energy and the University of California.
|
