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|
//
// Copyright 2015 Ettus Research LLC
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
#ifndef INCLUDED_ADF435X_HPP
#define INCLUDED_ADF435X_HPP
#include "adf4350_regs.hpp"
#include "adf4351_regs.hpp"
#include <uhd/exception.hpp>
#include <uhd/types/dict.hpp>
#include <uhd/types/ranges.hpp>
#include <uhd/utils/log.hpp>
#include <uhdlib/utils/math.hpp>
#include <boost/function.hpp>
#include <boost/math/special_functions/round.hpp>
#include <boost/thread.hpp>
#include <vector>
class adf435x_iface
{
public:
typedef std::shared_ptr<adf435x_iface> sptr;
typedef boost::function<void(std::vector<uint32_t>)> write_fn_t;
static sptr make_adf4350(write_fn_t write);
static sptr make_adf4351(write_fn_t write);
virtual ~adf435x_iface() = 0;
enum output_t { RF_OUTPUT_A, RF_OUTPUT_B };
enum prescaler_t { PRESCALER_4_5, PRESCALER_8_9 };
enum feedback_sel_t { FB_SEL_FUNDAMENTAL, FB_SEL_DIVIDED };
enum output_power_t {
OUTPUT_POWER_M4DBM,
OUTPUT_POWER_M1DBM,
OUTPUT_POWER_2DBM,
OUTPUT_POWER_5DBM
};
enum muxout_t {
MUXOUT_3STATE,
MUXOUT_DVDD,
MUXOUT_DGND,
MUXOUT_RDIV,
MUXOUT_NDIV,
MUXOUT_ALD,
MUXOUT_DLD
};
enum tuning_mode_t { TUNING_MODE_HIGH_RESOLUTION, TUNING_MODE_LOW_SPUR };
/**
* Charge Pump Currents
*/
enum charge_pump_current_t {
CHARGE_PUMP_CURRENT_0_31MA = 0,
CHARGE_PUMP_CURRENT_0_63MA = 1,
CHARGE_PUMP_CURRENT_0_94MA = 2,
CHARGE_PUMP_CURRENT_1_25MA = 3,
CHARGE_PUMP_CURRENT_1_56MA = 4,
CHARGE_PUMP_CURRENT_1_88MA = 5,
CHARGE_PUMP_CURRENT_2_19MA = 6,
CHARGE_PUMP_CURRENT_2_50MA = 7,
CHARGE_PUMP_CURRENT_2_81MA = 8,
CHARGE_PUMP_CURRENT_3_13MA = 9,
CHARGE_PUMP_CURRENT_3_44MA = 10,
CHARGE_PUMP_CURRENT_3_75MA = 11,
CHARGE_PUMP_CURRENT_4_07MA = 12,
CHARGE_PUMP_CURRENT_4_38MA = 13,
CHARGE_PUMP_CURRENT_4_69MA = 14,
CHARGE_PUMP_CURRENT_5_00MA = 15
};
virtual void set_reference_freq(double fref) = 0;
virtual void set_prescaler(prescaler_t prescaler) = 0;
virtual void set_feedback_select(feedback_sel_t fb_sel) = 0;
virtual void set_output_power(output_t output, output_power_t power) = 0;
void set_output_power(output_power_t power)
{
set_output_power(RF_OUTPUT_A, power);
}
virtual void set_output_enable(output_t output, bool enable) = 0;
virtual void set_muxout_mode(muxout_t mode) = 0;
//! Sets the tuning mode for subsequent tunes
/**
* High resolution mode will use the maximum modulus value to ensure an
* exact tune whenever possible. Low spur mode will try to find the "best"
* modulus for spur performance, which may result in loss of precision.
*
* To fully utilize low spur mode, the charge pump current should be
* decreased. This will vary based on board design. For example, for
* TwinRX LO2, the current is decreased from 1.88 mA to 1.25 mA. In
* addition, the 8/9 prescaler should be used instead of 4/5 whenever
* possible.
*/
virtual void set_tuning_mode(tuning_mode_t mode) = 0;
virtual void set_charge_pump_current(charge_pump_current_t cp_current) = 0;
virtual double set_charge_pump_current(double current, bool flush = false) = 0;
virtual uhd::meta_range_t get_charge_pump_current_range() = 0;
virtual uhd::range_t get_int_range() = 0;
virtual double set_frequency(
double target_freq, bool int_n_mode, bool flush = false) = 0;
virtual void commit(void) = 0;
};
template <typename adf435x_regs_t>
class adf435x_impl : public adf435x_iface
{
public:
adf435x_impl(write_fn_t write_fn)
: _write_fn(write_fn)
, _regs()
, _fb_after_divider(false)
, _reference_freq(0.0)
, _N_min(-1)
{
}
virtual ~adf435x_impl(){};
void set_reference_freq(double fref)
{
_reference_freq = fref;
}
void set_feedback_select(feedback_sel_t fb_sel)
{
_fb_after_divider = (fb_sel == FB_SEL_DIVIDED);
}
void set_prescaler(prescaler_t prescaler)
{
if (prescaler == PRESCALER_8_9) {
_regs.prescaler = adf435x_regs_t::PRESCALER_8_9;
_N_min = 75;
} else {
_regs.prescaler = adf435x_regs_t::PRESCALER_4_5;
_N_min = 23;
}
}
void set_output_power(output_t output, output_power_t power)
{
switch (output) {
case RF_OUTPUT_A:
switch (power) {
case OUTPUT_POWER_M4DBM:
_regs.output_power = adf435x_regs_t::OUTPUT_POWER_M4DBM;
break;
case OUTPUT_POWER_M1DBM:
_regs.output_power = adf435x_regs_t::OUTPUT_POWER_M1DBM;
break;
case OUTPUT_POWER_2DBM:
_regs.output_power = adf435x_regs_t::OUTPUT_POWER_2DBM;
break;
case OUTPUT_POWER_5DBM:
_regs.output_power = adf435x_regs_t::OUTPUT_POWER_5DBM;
break;
default:
UHD_THROW_INVALID_CODE_PATH();
}
break;
case RF_OUTPUT_B:
switch (power) {
case OUTPUT_POWER_M4DBM:
_regs.aux_output_power = adf435x_regs_t::AUX_OUTPUT_POWER_M4DBM;
break;
case OUTPUT_POWER_M1DBM:
_regs.aux_output_power = adf435x_regs_t::AUX_OUTPUT_POWER_M1DBM;
break;
case OUTPUT_POWER_2DBM:
_regs.aux_output_power = adf435x_regs_t::AUX_OUTPUT_POWER_2DBM;
break;
case OUTPUT_POWER_5DBM:
_regs.aux_output_power = adf435x_regs_t::AUX_OUTPUT_POWER_5DBM;
break;
default:
UHD_THROW_INVALID_CODE_PATH();
}
break;
default:
UHD_THROW_INVALID_CODE_PATH();
}
}
void set_output_enable(output_t output, bool enable)
{
switch (output) {
case RF_OUTPUT_A:
_regs.rf_output_enable = enable
? adf435x_regs_t::RF_OUTPUT_ENABLE_ENABLED
: adf435x_regs_t::RF_OUTPUT_ENABLE_DISABLED;
break;
case RF_OUTPUT_B:
_regs.aux_output_enable =
enable ? adf435x_regs_t::AUX_OUTPUT_ENABLE_ENABLED
: adf435x_regs_t::AUX_OUTPUT_ENABLE_DISABLED;
break;
}
}
void set_muxout_mode(muxout_t mode)
{
switch (mode) {
case MUXOUT_3STATE:
_regs.muxout = adf435x_regs_t::MUXOUT_3STATE;
break;
case MUXOUT_DVDD:
_regs.muxout = adf435x_regs_t::MUXOUT_DVDD;
break;
case MUXOUT_DGND:
_regs.muxout = adf435x_regs_t::MUXOUT_DGND;
break;
case MUXOUT_RDIV:
_regs.muxout = adf435x_regs_t::MUXOUT_RDIV;
break;
case MUXOUT_NDIV:
_regs.muxout = adf435x_regs_t::MUXOUT_NDIV;
break;
case MUXOUT_ALD:
_regs.muxout = adf435x_regs_t::MUXOUT_ANALOG_LD;
break;
case MUXOUT_DLD:
_regs.muxout = adf435x_regs_t::MUXOUT_DLD;
break;
default:
UHD_THROW_INVALID_CODE_PATH();
}
}
void set_tuning_mode(tuning_mode_t mode)
{
// New mode applies to subsequent tunes i.e. do not re-tune now
_tuning_mode = mode;
_regs.low_noise_and_spur = (_tuning_mode == TUNING_MODE_HIGH_RESOLUTION)
? adf435x_regs_t::LOW_NOISE_AND_SPUR_LOW_SPUR
: adf435x_regs_t::LOW_NOISE_AND_SPUR_LOW_NOISE;
_regs.phase_12_bit = (_tuning_mode == TUNING_MODE_HIGH_RESOLUTION) ? 0 : 1;
}
void set_charge_pump_current(charge_pump_current_t cp_current)
{
switch (cp_current) {
case CHARGE_PUMP_CURRENT_0_31MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_0_31MA;
break;
case CHARGE_PUMP_CURRENT_0_63MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_0_63MA;
break;
case CHARGE_PUMP_CURRENT_0_94MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_0_94MA;
break;
case CHARGE_PUMP_CURRENT_1_25MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_1_25MA;
break;
case CHARGE_PUMP_CURRENT_1_56MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_1_56MA;
break;
case CHARGE_PUMP_CURRENT_1_88MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_1_88MA;
break;
case CHARGE_PUMP_CURRENT_2_19MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_2_19MA;
break;
case CHARGE_PUMP_CURRENT_2_50MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_2_50MA;
break;
case CHARGE_PUMP_CURRENT_2_81MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_2_81MA;
break;
case CHARGE_PUMP_CURRENT_3_13MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_3_13MA;
break;
case CHARGE_PUMP_CURRENT_3_44MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_3_44MA;
break;
case CHARGE_PUMP_CURRENT_3_75MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_3_75MA;
break;
case CHARGE_PUMP_CURRENT_4_07MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_4_07MA;
break;
case CHARGE_PUMP_CURRENT_4_38MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_4_38MA;
break;
case CHARGE_PUMP_CURRENT_4_69MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_4_69MA;
break;
case CHARGE_PUMP_CURRENT_5_00MA:
_regs.charge_pump_current = adf435x_regs_t::CHARGE_PUMP_CURRENT_5_00MA;
break;
default:
UHD_THROW_INVALID_CODE_PATH();
}
}
double set_charge_pump_current(const double current, const bool flush)
{
const auto cp_range = get_charge_pump_current_range();
const auto coerced_current = cp_range.clip(current, true);
const int current_step = std::round((coerced_current / cp_range.step()) - 1);
UHD_ASSERT_THROW(current_step >= 0 and current_step < 16);
set_charge_pump_current(
static_cast<adf435x_iface::charge_pump_current_t>(current_step));
if (flush) {
commit();
}
if (std::abs(current - coerced_current) > 0.01e-6) {
UHD_LOG_WARNING("ADF435x",
"Requested charge pump current was coerced! Requested: "
<< std::setw(4) << current << " A Actual: " << coerced_current
<< " A");
}
return coerced_current;
}
uhd::meta_range_t get_charge_pump_current_range()
{
return uhd::meta_range_t(.3125e-6, 5e-6, .3125e-6);
}
uhd::range_t get_int_range()
{
if (_N_min < 0)
throw uhd::runtime_error("set_prescaler must be called before get_int_range");
return uhd::range_t(_N_min, 4095);
}
double set_frequency(double target_freq, bool int_n_mode, bool flush = false)
{
static const double REF_DOUBLER_THRESH_FREQ = 12.5e6;
static const double PFD_FREQ_MAX = 25.0e6;
static const double BAND_SEL_FREQ_MAX = 100e3;
static const double VCO_FREQ_MIN = 2.2e9;
static const double VCO_FREQ_MAX = 4.4e9;
// Default invalid value for actual_freq
double actual_freq = 0;
uhd::range_t rf_divider_range = _get_rfdiv_range();
uhd::range_t int_range = get_int_range();
double pfd_freq = 0;
uint16_t R = 0, BS = 0, N = 0, FRAC = 0, MOD = 0;
uint16_t RFdiv = static_cast<uint16_t>(rf_divider_range.start());
bool D = false, T = false;
// Reference doubler for 50% duty cycle
D = (_reference_freq <= REF_DOUBLER_THRESH_FREQ);
// increase RF divider until acceptable VCO frequency
double vco_freq = target_freq;
while (vco_freq < VCO_FREQ_MIN
&& RFdiv < static_cast<uint16_t>(rf_divider_range.stop())) {
vco_freq *= 2;
RFdiv *= 2;
}
/*
* The goal here is to loop though possible R dividers,
* band select clock dividers, N (int) dividers, and FRAC
* (frac) dividers.
*
* Calculate the N and F dividers for each set of values.
* The loop exits when it meets all of the constraints.
* The resulting loop values are loaded into the registers.
*
* from pg.21
*
* f_pfd = f_ref*(1+D)/(R*(1+T))
* f_vco = (N + (FRAC/MOD))*f_pfd
* N = f_vco/f_pfd - FRAC/MOD = f_vco*((R*(T+1))/(f_ref*(1+D))) - FRAC/MOD
* f_actual = f_vco/RFdiv)
*/
double feedback_freq = _fb_after_divider ? target_freq : vco_freq;
for (R = 1; R <= 1023; R += 1) {
// PFD input frequency = f_ref/R ... ignoring Reference doubler/divide-by-2 (D
// & T)
pfd_freq = _reference_freq * (D ? 2 : 1) / (R * (T ? 2 : 1));
// keep the PFD frequency at or below 25MHz (Loop Filter Bandwidth)
if (pfd_freq > PFD_FREQ_MAX)
continue;
// First, ignore fractional part of tuning
N = uint16_t(std::floor(feedback_freq / pfd_freq));
// keep N > minimum int divider requirement
if (N < static_cast<uint16_t>(int_range.start()))
continue;
for (BS = 1; BS <= 255; BS += 1) {
// keep the band select frequency at or below band_sel_freq_max
// constraint on band select clock
if (pfd_freq / BS > BAND_SEL_FREQ_MAX)
continue;
goto done_loop;
}
}
done_loop:
double frac_part = (feedback_freq / pfd_freq) - N;
if (int_n_mode) {
if (frac_part >= 0.5) {
// Round integer such that actual freq is closest to target
N++;
}
FRAC = 0;
MOD = 2;
} else if (_tuning_mode == TUNING_MODE_LOW_SPUR) {
std::tie(FRAC, MOD) =
uhd::math::rational_approximation(frac_part, 4095, 0.0001);
if (MOD < 2) {
FRAC *= 2;
MOD *= 2;
}
} else {
MOD = 4095; // max fractional accuracy
FRAC = static_cast<uint16_t>(std::round(frac_part * MOD));
}
// Reference divide-by-2 for 50% duty cycle
// if R even, move one divide by 2 to to regs.reference_divide_by_2
if (R % 2 == 0) {
T = true;
R /= 2;
}
// Typical phase resync time documented in data sheet pg.24
static const double PHASE_RESYNC_TIME = 400e-6;
// If feedback after divider, then compensation for the divider is pulled into the
// INT value
int rf_div_compensation = _fb_after_divider ? 1 : RFdiv;
// Compute the actual frequency in terms of _reference_freq, N, FRAC, MOD, D, R
// and T.
actual_freq = (double((N + (double(FRAC) / double(MOD)))
* (_reference_freq * (D ? 2 : 1) / (R * (T ? 2 : 1)))))
/ rf_div_compensation;
uint16_t clock_div = std::max<uint16_t>(
1, uint16_t(std::ceil(PHASE_RESYNC_TIME * pfd_freq / MOD)));
if (clock_div > 4095) {
// if clock_div is larger than 12-bits, increase modulus so it
// fits. Asserts later will ensure these values are not too large
FRAC *= (clock_div >> 12) + 1;
MOD *= (clock_div >> 12) + 1;
clock_div = uint16_t(std::ceil(PHASE_RESYNC_TIME * pfd_freq / MOD));
}
_regs.frac_12_bit = FRAC;
_regs.int_16_bit = N;
_regs.mod_12_bit = MOD;
_regs.clock_divider_12_bit = clock_div;
_regs.feedback_select = _fb_after_divider
? adf435x_regs_t::FEEDBACK_SELECT_DIVIDED
: adf435x_regs_t::FEEDBACK_SELECT_FUNDAMENTAL;
_regs.clock_div_mode = _fb_after_divider
? adf435x_regs_t::CLOCK_DIV_MODE_RESYNC_ENABLE
: adf435x_regs_t::CLOCK_DIV_MODE_FAST_LOCK;
_regs.r_counter_10_bit = R;
_regs.reference_divide_by_2 = T ? adf435x_regs_t::REFERENCE_DIVIDE_BY_2_ENABLED
: adf435x_regs_t::REFERENCE_DIVIDE_BY_2_DISABLED;
_regs.reference_doubler = D ? adf435x_regs_t::REFERENCE_DOUBLER_ENABLED
: adf435x_regs_t::REFERENCE_DOUBLER_DISABLED;
_regs.band_select_clock_div = uint8_t(BS);
_regs.rf_divider_select =
static_cast<typename adf435x_regs_t::rf_divider_select_t>(
_get_rfdiv_setting(RFdiv));
_regs.ldf = int_n_mode ? adf435x_regs_t::LDF_INT_N : adf435x_regs_t::LDF_FRAC_N;
// clang-format off
UHD_LOG_TRACE("ADF435X", boost::format(
"ADF 435X Frequencies (MHz): REQUESTED=%0.9f, ACTUAL=%0.9f")
% (target_freq / 1e6) % (actual_freq / 1e6));
UHD_LOG_TRACE("ADF435X", boost::format(
"ADF 435X Intermediates (MHz): Feedback=%0.2f, VCO=%0.2f, PFD=%0.2f, BAND=%0.2f, REF=%0.2f")
% (feedback_freq / 1e6) % (vco_freq / 1e6) % (pfd_freq / 1e6) % (pfd_freq / BS / 1e6) % (_reference_freq / 1e6));
UHD_LOG_TRACE("ADF435X",
"ADF 435X Tuning: " << ((int_n_mode) ? "Integer-N" : "Fractional"));
UHD_LOG_TRACE("ADF435X", boost::format(
"ADF 435X Settings: R=%d, BS=%d, N=%d, FRAC=%d, MOD=%d, T=%d, D=%d, RFdiv=%d")
% R % BS % N % FRAC % MOD % T % D % RFdiv);
// clang-format on
UHD_ASSERT_THROW((_regs.frac_12_bit & ((uint16_t)~0xFFF)) == 0);
UHD_ASSERT_THROW((_regs.mod_12_bit & ((uint16_t)~0xFFF)) == 0);
UHD_ASSERT_THROW((_regs.clock_divider_12_bit & ((uint16_t)~0xFFF)) == 0);
UHD_ASSERT_THROW((_regs.r_counter_10_bit & ((uint16_t)~0x3FF)) == 0);
UHD_ASSERT_THROW(vco_freq >= VCO_FREQ_MIN and vco_freq <= VCO_FREQ_MAX);
UHD_ASSERT_THROW(RFdiv >= static_cast<uint16_t>(rf_divider_range.start()));
UHD_ASSERT_THROW(RFdiv <= static_cast<uint16_t>(rf_divider_range.stop()));
UHD_ASSERT_THROW(_regs.int_16_bit >= static_cast<uint16_t>(int_range.start()));
UHD_ASSERT_THROW(_regs.int_16_bit <= static_cast<uint16_t>(int_range.stop()));
if (flush)
commit();
return actual_freq;
}
void commit()
{
// reset counters
_regs.counter_reset = adf435x_regs_t::COUNTER_RESET_ENABLED;
std::vector<uint32_t> regs;
regs.push_back(_regs.get_reg(uint32_t(2)));
_write_fn(regs);
_regs.counter_reset = adf435x_regs_t::COUNTER_RESET_DISABLED;
// write the registers
// correct power-up sequence to write registers (5, 4, 3, 2, 1, 0)
regs.clear();
for (int addr = 5; addr >= 0; addr--) {
regs.push_back(_regs.get_reg(uint32_t(addr)));
}
_write_fn(regs);
}
protected:
uhd::range_t _get_rfdiv_range();
int _get_rfdiv_setting(uint16_t div);
write_fn_t _write_fn;
adf435x_regs_t _regs;
double _fb_after_divider;
double _reference_freq;
int _N_min;
tuning_mode_t _tuning_mode;
};
template <>
inline uhd::range_t adf435x_impl<adf4350_regs_t>::_get_rfdiv_range()
{
return uhd::range_t(1, 16);
}
template <>
inline uhd::range_t adf435x_impl<adf4351_regs_t>::_get_rfdiv_range()
{
return uhd::range_t(1, 64);
}
template <>
inline int adf435x_impl<adf4350_regs_t>::_get_rfdiv_setting(uint16_t div)
{
switch (div) {
case 1:
return int(adf4350_regs_t::RF_DIVIDER_SELECT_DIV1);
case 2:
return int(adf4350_regs_t::RF_DIVIDER_SELECT_DIV2);
case 4:
return int(adf4350_regs_t::RF_DIVIDER_SELECT_DIV4);
case 8:
return int(adf4350_regs_t::RF_DIVIDER_SELECT_DIV8);
case 16:
return int(adf4350_regs_t::RF_DIVIDER_SELECT_DIV16);
default:
UHD_THROW_INVALID_CODE_PATH();
}
}
template <>
inline int adf435x_impl<adf4351_regs_t>::_get_rfdiv_setting(uint16_t div)
{
switch (div) {
case 1:
return int(adf4351_regs_t::RF_DIVIDER_SELECT_DIV1);
case 2:
return int(adf4351_regs_t::RF_DIVIDER_SELECT_DIV2);
case 4:
return int(adf4351_regs_t::RF_DIVIDER_SELECT_DIV4);
case 8:
return int(adf4351_regs_t::RF_DIVIDER_SELECT_DIV8);
case 16:
return int(adf4351_regs_t::RF_DIVIDER_SELECT_DIV16);
case 32:
return int(adf4351_regs_t::RF_DIVIDER_SELECT_DIV32);
case 64:
return int(adf4351_regs_t::RF_DIVIDER_SELECT_DIV64);
default:
UHD_THROW_INVALID_CODE_PATH();
}
}
#endif // INCLUDED_ADF435X_HPP
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