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authorIan Buckley <github@ionconcepts.com>2015-09-03 15:55:05 -0700
committerMartin Braun <martin.braun@ettus.com>2015-09-08 09:24:15 -0700
commitcc6c82befcf30f0b8488be918f817b3b9a3e7808 (patch)
treed1f7b85fb77cb660806c2b91cc746dfafdb4830e /host/lib
parent43fdc0e84ba577adc799a159c28016bd09a8992d (diff)
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cores: Corrected scaling_adjustment calculation
Compensate for headroom required to rotate a signal in the CORDIC. Fixes some CORDIC-related clipping issues, that reduced ENOB to 15 or 14.5 bits.
Diffstat (limited to 'host/lib')
-rw-r--r--host/lib/usrp/cores/rx_dsp_core_3000.cpp27
-rw-r--r--host/lib/usrp/cores/tx_dsp_core_3000.cpp17
-rw-r--r--host/lib/usrp/x300/x300_impl.cpp8
-rw-r--r--host/lib/usrp/x300/x300_impl.hpp2
4 files changed, 42 insertions, 12 deletions
diff --git a/host/lib/usrp/cores/rx_dsp_core_3000.cpp b/host/lib/usrp/cores/rx_dsp_core_3000.cpp
index 18dabade0..035bc6a3f 100644
--- a/host/lib/usrp/cores/rx_dsp_core_3000.cpp
+++ b/host/lib/usrp/cores/rx_dsp_core_3000.cpp
@@ -173,20 +173,35 @@ public:
}
}
- // Calculate CIC decimation (i.e., without halfband decimators)
- // Calculate closest multiplier constant to reverse gain absent scale multipliers
+ // Caclulate algorithmic gain of CIC for a given decimation.
+ // For Ettus CIC R=decim, M=1, N=4. Gain = (R * M) ^ N
const double rate_pow = std::pow(double(decim & 0xff), 4);
- _scaling_adjustment = std::pow(2, ceil_log2(rate_pow))/(1.65*rate_pow);
+ // Calculate compensation gain values for algorithmic gain of CORDIC and CIC taking into account
+ // gain compensation blocks already hardcoded in place in DDC (that provide simple 1/2^n gain compensation).
+ // CORDIC algorithmic gain limits asymptotically around 1.647 after many iterations.
+ //
+ // The polar rotation of [I,Q] = [1,1] by Pi/8 also yields max magnitude of SQRT(2) (~1.4142) however
+ // input to the CORDIC thats outside the unit circle can only be sourced from a saturated RF frontend.
+ // To provide additional dynamic range head room accordingly using scale factor applied at egress from DDC would
+ // cost us small signal performance, thus we do no provide compensation gain for a saturated front end and allow
+ // the signal to clip in the H/W as needed. If we wished to avoid the signal clipping in these circumstances then adjust code to read:
+ // _scaling_adjustment = std::pow(2, ceil_log2(rate_pow))/(1.648*rate_pow*1.415);
+ _scaling_adjustment = std::pow(2, ceil_log2(rate_pow))/(1.648*rate_pow);
+
this->update_scalar();
return _tick_rate/decim_rate;
}
+ // Calculate compensation gain values for algorithmic gain of CORDIC and CIC taking into account
+ // gain compensation blocks already hardcoded in place in DDC (that provide simple 1/2^n gain compensation).
+ // Further more factor in OTW format which adds further gain factor to weight output samples correctly.
void update_scalar(void){
- const double factor = 1.0 + std::max(ceil_log2(_scaling_adjustment), 0.0);
- const double target_scalar = (1 << (_is_b200 ? 17 : 15))*_scaling_adjustment/_dsp_extra_scaling/factor;
+ const double target_scalar = (1 << (_is_b200 ? 16 : 15))*_scaling_adjustment/_dsp_extra_scaling;
const boost::int32_t actual_scalar = boost::math::iround(target_scalar);
- _fxpt_scalar_correction = target_scalar/actual_scalar*factor; //should be small
+ // Calculate the error introduced by using integer representation for the scalar, can be corrected in host later.
+ _fxpt_scalar_correction = target_scalar/actual_scalar;
+ // Write DDC with scaling correction for CIC and CORDIC that maximizes dynamic range in 32/16/12/8bits.
_iface->poke32(REG_DSP_RX_SCALE_IQ, actual_scalar);
}
diff --git a/host/lib/usrp/cores/tx_dsp_core_3000.cpp b/host/lib/usrp/cores/tx_dsp_core_3000.cpp
index 93b70435f..7e447ae7d 100644
--- a/host/lib/usrp/cores/tx_dsp_core_3000.cpp
+++ b/host/lib/usrp/cores/tx_dsp_core_3000.cpp
@@ -110,20 +110,25 @@ public:
) % interp_rate % (_tick_rate/1e6) % (rate/1e6);
}
- // Calculate CIC interpolation (i.e., without halfband interpolators)
- // Calculate closest multiplier constant to reverse gain absent scale multipliers
+ // Caclulate algorithmic gain of CIC for a given interpolation
+ // For Ettus CIC R=decim, M=1, N=3. Gain = (R * M) ^ N
const double rate_pow = std::pow(double(interp & 0xff), 3);
- _scaling_adjustment = std::pow(2, ceil_log2(rate_pow))/(1.65*rate_pow);
+ // Calculate compensation gain values for algorithmic gain of CORDIC and CIC taking into account
+ // gain compensation blocks already hardcoded in place in DDC (that provide simple 1/2^n gain compensation).
+ // CORDIC algorithmic gain limits asymptotically around 1.647 after many iterations.
+ _scaling_adjustment = std::pow(2, ceil_log2(rate_pow))/(1.648*rate_pow);
this->update_scalar();
return _tick_rate/interp_rate;
}
+ // Calculate compensation gain values for algorithmic gain of CORDIC and CIC taking into account
+ // gain compensation blocks already hardcoded in place in DDC (that provide simple 1/2^n gain compensation).
+ // Further more factor in OTW format which adds further gain factor to weight output samples correctly.
void update_scalar(void){
- const double factor = 1.0 + std::max(ceil_log2(_scaling_adjustment), 0.0);
- const double target_scalar = (1 << 17)*_scaling_adjustment/_dsp_extra_scaling/factor;
+ const double target_scalar = (1 << 16)*_scaling_adjustment/_dsp_extra_scaling;
const boost::int32_t actual_scalar = boost::math::iround(target_scalar);
- _fxpt_scalar_correction = target_scalar/actual_scalar*factor; //should be small
+ _fxpt_scalar_correction = target_scalar/actual_scalar; //should be small
_iface->poke32(REG_DSP_TX_SCALE_IQ, actual_scalar);
}
diff --git a/host/lib/usrp/x300/x300_impl.cpp b/host/lib/usrp/x300/x300_impl.cpp
index f57556a8b..1e424414e 100644
--- a/host/lib/usrp/x300/x300_impl.cpp
+++ b/host/lib/usrp/x300/x300_impl.cpp
@@ -1334,6 +1334,14 @@ void x300_impl::register_loopback_self_test(wb_iface::sptr iface)
UHD_MSG(status) << ((test_fail)? " fail" : "pass") << std::endl;
}
+void x300_impl::radio_loopback(wb_iface::sptr iface, const bool on)
+{
+ iface->poke32(radio::sr_addr(radio::LOOPBACK), (on ? 0x1 : 0x0));
+ UHD_MSG(status) << ((on)? "Radio Loopback On" : "Radio Loopback Off") << std::endl;
+}
+
+
+
/***********************************************************************
* clock and time control logic
**********************************************************************/
diff --git a/host/lib/usrp/x300/x300_impl.hpp b/host/lib/usrp/x300/x300_impl.hpp
index 78c497ad9..1630047af 100644
--- a/host/lib/usrp/x300/x300_impl.hpp
+++ b/host/lib/usrp/x300/x300_impl.hpp
@@ -250,6 +250,8 @@ private:
void register_loopback_self_test(uhd::wb_iface::sptr iface);
+ void radio_loopback(uhd::wb_iface::sptr iface, const bool on);
+
/*! \brief Initialize the radio component on a given slot.
*
* Call this function once per slot (A and B) and motherboard to initialize all the radio components.