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@ -9,17 +9,19 @@ |
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* and cos of the same frequency. The pair of mixer outputs are |
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* and cos of the same frequency. The pair of mixer outputs are |
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* referred to as i and q. The conversion in frequency is either |
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* referred to as i and q. The conversion in frequency is either |
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* up or down, and a pair of filters on i and q determine which is allow |
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* up or down, and a pair of filters on i and q determine which is allow |
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* to pass to the output.
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* to pass to the output. |
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*
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* |
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* April 2021 - Alternatively, there can be two inputs to 0 (left) and 1 |
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* April 2021 - Alternatively, there can be two inputs to 0 (left) and 1 |
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* (right) feeding the two mixers separately. This covers all transmit |
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* (right) feeding the two mixers separately. This covers all transmit |
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* and receive situations. |
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* and receive situations. |
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*
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* |
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* The sin/cos LO is from synth_sin_cos_f32.cpp See that for details. |
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* The sin/cos LO is from synth_sin_cos_f32.cpp See that for details. |
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*
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* |
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* Inputs are either real or I-Q per bool twoChannel. Rev Apr 2021 |
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* Inputs are either real or I-Q per bool twoChannel. Rev Apr 2021 |
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*
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* |
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* MIT License, Use at your own risk. |
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* MIT License, Use at your own risk. |
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* |
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* Rev 28 Mar 2022 Correctedslight interpolation error. RSL |
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*/ |
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*/ |
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#include "RadioIQMixer_F32.h" |
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#include "RadioIQMixer_F32.h" |
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@ -47,7 +49,7 @@ void RadioIQMixer_F32::update(void) { |
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// Try to get a pair of blocks for the IQ output
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// Try to get a pair of blocks for the IQ output
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blockOut_i = AudioStream_F32::allocate_f32(); |
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blockOut_i = AudioStream_F32::allocate_f32(); |
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if (!blockOut_i){ // Didn't have any
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if (!blockOut_i){ // Didn't have any
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if(errorPrintIQM) Serial.println("IQMIXER-ERR: No I output memory"); |
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if(errorPrintIQM) Serial.println("IQMIXER-ERR: No I output memory"); |
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AudioStream_F32::release(blockIn0); |
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AudioStream_F32::release(blockIn0); |
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if(twoChannel) |
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if(twoChannel) |
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@ -78,8 +80,8 @@ void RadioIQMixer_F32::update(void) { |
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a = sinTable512_f32[index]; |
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a = sinTable512_f32[index]; |
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b = sinTable512_f32[index+1]; |
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b = sinTable512_f32[index+1]; |
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// Linear interpolation and multiplying (DBMixer) with input
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// Linear interpolation and multiplying (DBMixer) with input
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blockOut_i->data[i] = blockIn0->data[i] * (a + 0.001953125*(b-a)*deltaPhase); |
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blockOut_i->data[i] = blockIn0->data[i] * (a + (b-a)*deltaPhase); |
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/* Repeat for cosine by adding 90 degrees phase */ |
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/* Repeat for cosine by adding 90 degrees phase */ |
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index = (index + 128) & 0x01ff; |
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index = (index + 128) & 0x01ff; |
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/* Read two nearest values of input value from the sin table */ |
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/* Read two nearest values of input value from the sin table */ |
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@ -87,9 +89,9 @@ void RadioIQMixer_F32::update(void) { |
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b = sinTable512_f32[index+1]; |
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b = sinTable512_f32[index+1]; |
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/* deltaPhase will be the same as used for sin */ |
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/* deltaPhase will be the same as used for sin */ |
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if(twoChannel) |
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if(twoChannel) |
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blockOut_q->data[i] = blockIn1->data[i]*(a + 0.001953125*(b-a)*deltaPhase); |
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blockOut_q->data[i] = blockIn1->data[i]*(a + (b-a)*deltaPhase); |
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else |
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else |
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blockOut_q->data[i] = blockIn0->data[i]*(a + 0.001953125*(b-a)*deltaPhase); |
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blockOut_q->data[i] = blockIn0->data[i]*(a + (b-a)*deltaPhase); |
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} |
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} |
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} |
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} |
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else { // Do a more flexible update, i.e., not doSimple
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else { // Do a more flexible update, i.e., not doSimple
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@ -103,8 +105,8 @@ void RadioIQMixer_F32::update(void) { |
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b = sinTable512_f32[index+1]; |
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b = sinTable512_f32[index+1]; |
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// We now have a sine value, so multiply with the input data and save
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// We now have a sine value, so multiply with the input data and save
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// Linear interpolate sine and multiply with the input and amplitude (about 1.0)
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// Linear interpolate sine and multiply with the input and amplitude (about 1.0)
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blockOut_i->data[i] = amplitude_pk * blockIn0->data[i] * (a + 0.001953125*(b-a)*deltaPhase); |
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blockOut_i->data[i] = amplitude_pk * blockIn0->data[i] * (a + (b-a)*deltaPhase); |
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/* Shift forward phaseS_C and get cos. First, the calculation of index of the table */ |
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/* Shift forward phaseS_C and get cos. First, the calculation of index of the table */ |
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phaseC = phaseS + phaseS_C; |
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phaseC = phaseS + phaseS_C; |
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if (phaseC > 512.0f) phaseC -= 512.0f; |
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if (phaseC > 512.0f) phaseC -= 512.0f; |
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@ -115,9 +117,9 @@ void RadioIQMixer_F32::update(void) { |
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b = sinTable512_f32[index+1]; |
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b = sinTable512_f32[index+1]; |
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// Same as sin, but leave amplitude of LO at +/- 1.0
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// Same as sin, but leave amplitude of LO at +/- 1.0
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if(twoChannel) |
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if(twoChannel) |
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blockOut_q->data[i] = blockIn1->data[i]*(a + 0.001953125*(b-a)*deltaPhase); |
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blockOut_q->data[i] = blockIn1->data[i]*(a + (b-a)*deltaPhase); |
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else |
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else |
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blockOut_q->data[i] = blockIn0->data[i]*(a + 0.001953125*(b-a)*deltaPhase); |
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blockOut_q->data[i] = blockIn0->data[i]*(a + (b-a)*deltaPhase); |
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} |
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} |
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} |
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} |
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AudioStream_F32::release(blockIn0); // Done with this
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AudioStream_F32::release(blockIn0); // Done with this
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