//
// Copyright 2010-2011 Ettus Research LLC
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see .
//
#include "clock_ctrl.hpp"
#include "ad9510_regs.hpp"
#include "usrp2_regs.hpp" //spi slave constants
#include "usrp2_clk_regs.hpp"
#include
#include
#include
#include
#include
using namespace uhd;
static const bool enb_test_clk = false;
/*!
* A usrp2 clock control specific to the ad9510 ic.
*/
class usrp2_clock_ctrl_impl : public usrp2_clock_ctrl{
public:
usrp2_clock_ctrl_impl(usrp2_iface::sptr iface){
_iface = iface;
clk_regs = usrp2_clk_regs_t(_iface->get_rev());
_ad9510_regs.cp_current_setting = ad9510_regs_t::CP_CURRENT_SETTING_3_0MA;
this->write_reg(clk_regs.pll_3);
// Setup the clock registers to 100MHz:
// This was already done by the firmware (or the host couldnt communicate).
// We could remove this part, and just leave it to the firmware.
// But why not leave it in for those who want to mess with clock settings?
// 100mhz = 10mhz/R * (P*B + A)
_ad9510_regs.pll_power_down = ad9510_regs_t::PLL_POWER_DOWN_NORMAL;
_ad9510_regs.prescaler_value = ad9510_regs_t::PRESCALER_VALUE_DIV2;
this->write_reg(clk_regs.pll_4);
_ad9510_regs.acounter = 0;
this->write_reg(clk_regs.acounter);
_ad9510_regs.bcounter_msb = 0;
_ad9510_regs.bcounter_lsb = 5;
this->write_reg(clk_regs.bcounter_msb);
this->write_reg(clk_regs.bcounter_lsb);
_ad9510_regs.ref_counter_msb = 0;
_ad9510_regs.ref_counter_lsb = 1; // r divider = 1
this->write_reg(clk_regs.ref_counter_msb);
this->write_reg(clk_regs.ref_counter_lsb);
/* regs will be updated in commands below */
this->enable_external_ref(false);
this->enable_rx_dboard_clock(false);
this->enable_tx_dboard_clock(false);
this->enable_mimo_clock_out(false);
/* private clock enables, must be set here */
this->enable_dac_clock(true);
this->enable_adc_clock(true);
this->enable_test_clock(enb_test_clk);
}
~usrp2_clock_ctrl_impl(void){
//power down clock outputs
this->enable_external_ref(false);
this->enable_rx_dboard_clock(false);
this->enable_tx_dboard_clock(false);
this->enable_dac_clock(false);
this->enable_adc_clock(false);
this->enable_mimo_clock_out(false);
this->enable_test_clock(false);
}
void enable_mimo_clock_out(bool enb){
//calculate the low and high dividers
size_t divider = size_t(this->get_master_clock_rate()/10e6);
size_t high = divider/2;
size_t low = divider - high;
switch(clk_regs.exp){
case 2: //U2 rev 3
_ad9510_regs.power_down_lvpecl_out2 = enb?
ad9510_regs_t::POWER_DOWN_LVPECL_OUT2_NORMAL :
ad9510_regs_t::POWER_DOWN_LVPECL_OUT2_SAFE_PD;
_ad9510_regs.output_level_lvpecl_out2 = ad9510_regs_t::OUTPUT_LEVEL_LVPECL_OUT2_810MV;
//set the registers (divider - 1)
_ad9510_regs.divider_low_cycles_out2 = low - 1;
_ad9510_regs.divider_high_cycles_out2 = high - 1;
_ad9510_regs.bypass_divider_out2 = 0;
break;
case 5: //U2 rev 4
_ad9510_regs.power_down_lvds_cmos_out5 = enb? 0 : 1;
_ad9510_regs.lvds_cmos_select_out5 = ad9510_regs_t::LVDS_CMOS_SELECT_OUT5_LVDS;
_ad9510_regs.output_level_lvds_out5 = ad9510_regs_t::OUTPUT_LEVEL_LVDS_OUT5_1_75MA;
//set the registers (divider - 1)
_ad9510_regs.divider_low_cycles_out5 = low - 1;
_ad9510_regs.divider_high_cycles_out5 = high - 1;
_ad9510_regs.bypass_divider_out5 = 0;
break;
case 6: //U2+
_ad9510_regs.power_down_lvds_cmos_out6 = enb? 0 : 1;
_ad9510_regs.lvds_cmos_select_out6 = ad9510_regs_t::LVDS_CMOS_SELECT_OUT6_LVDS;
_ad9510_regs.output_level_lvds_out6 = ad9510_regs_t::OUTPUT_LEVEL_LVDS_OUT6_1_75MA;
//set the registers (divider - 1)
_ad9510_regs.divider_low_cycles_out6 = low - 1;
_ad9510_regs.divider_high_cycles_out6 = high - 1;
_ad9510_regs.bypass_divider_out5 = 0;
break;
default:
break;
}
this->write_reg(clk_regs.output(clk_regs.exp));
this->write_reg(clk_regs.div_lo(clk_regs.exp));
this->update_regs();
}
//uses output clock 7 (cmos)
void enable_rx_dboard_clock(bool enb){
_ad9510_regs.power_down_lvds_cmos_out7 = enb? 0 : 1;
_ad9510_regs.lvds_cmos_select_out7 = ad9510_regs_t::LVDS_CMOS_SELECT_OUT7_CMOS;
_ad9510_regs.output_level_lvds_out7 = ad9510_regs_t::OUTPUT_LEVEL_LVDS_OUT7_1_75MA;
this->write_reg(clk_regs.output(clk_regs.rx_db));
this->update_regs();
}
void set_rate_rx_dboard_clock(double rate){
assert_has(get_rates_rx_dboard_clock(), rate, "rx dboard clock rate");
size_t divider = size_t(get_master_clock_rate()/rate);
//bypass when the divider ratio is one
_ad9510_regs.bypass_divider_out7 = (divider == 1)? 1 : 0;
//calculate the low and high dividers
size_t high = divider/2;
size_t low = divider - high;
//set the registers (divider - 1)
_ad9510_regs.divider_low_cycles_out7 = low - 1;
_ad9510_regs.divider_high_cycles_out7 = high - 1;
//write the registers
this->write_reg(clk_regs.div_lo(clk_regs.rx_db));
this->write_reg(clk_regs.div_hi(clk_regs.rx_db));
this->update_regs();
}
std::vector get_rates_rx_dboard_clock(void){
std::vector rates;
for (size_t i = 1; i <= 16+16; i++) rates.push_back(get_master_clock_rate()/i);
return rates;
}
//uses output clock 6 (cmos) on USRP2 and output clock 5 (cmos) on USRP2+
void enable_tx_dboard_clock(bool enb){
switch(clk_regs.tx_db) {
case 5: //USRP2+
_ad9510_regs.power_down_lvds_cmos_out5 = enb? 0 : 1;
_ad9510_regs.lvds_cmos_select_out5 = ad9510_regs_t::LVDS_CMOS_SELECT_OUT5_CMOS;
_ad9510_regs.output_level_lvds_out5 = ad9510_regs_t::OUTPUT_LEVEL_LVDS_OUT5_1_75MA;
break;
case 6: //USRP2
_ad9510_regs.power_down_lvds_cmos_out6 = enb? 0 : 1;
_ad9510_regs.lvds_cmos_select_out6 = ad9510_regs_t::LVDS_CMOS_SELECT_OUT6_CMOS;
_ad9510_regs.output_level_lvds_out6 = ad9510_regs_t::OUTPUT_LEVEL_LVDS_OUT6_1_75MA;
break;
}
this->write_reg(clk_regs.output(clk_regs.tx_db));
this->update_regs();
}
void set_rate_tx_dboard_clock(double rate){
assert_has(get_rates_tx_dboard_clock(), rate, "tx dboard clock rate");
size_t divider = size_t(get_master_clock_rate()/rate);
//bypass when the divider ratio is one
_ad9510_regs.bypass_divider_out6 = (divider == 1)? 1 : 0;
//calculate the low and high dividers
size_t high = divider/2;
size_t low = divider - high;
switch(clk_regs.tx_db) {
case 5: //USRP2+
_ad9510_regs.bypass_divider_out5 = (divider == 1)? 1 : 0;
_ad9510_regs.divider_low_cycles_out5 = low - 1;
_ad9510_regs.divider_high_cycles_out5 = high - 1;
break;
case 6: //USRP2
//bypass when the divider ratio is one
_ad9510_regs.bypass_divider_out6 = (divider == 1)? 1 : 0;
//set the registers (divider - 1)
_ad9510_regs.divider_low_cycles_out6 = low - 1;
_ad9510_regs.divider_high_cycles_out6 = high - 1;
break;
}
//write the registers
this->write_reg(clk_regs.div_hi(clk_regs.tx_db));
this->write_reg(clk_regs.div_lo(clk_regs.tx_db));
this->update_regs();
}
std::vector get_rates_tx_dboard_clock(void){
return get_rates_rx_dboard_clock(); //same master clock, same dividers...
}
void enable_test_clock(bool enb) {
_ad9510_regs.power_down_lvpecl_out0 = enb?
ad9510_regs_t::POWER_DOWN_LVPECL_OUT0_NORMAL :
ad9510_regs_t::POWER_DOWN_LVPECL_OUT0_SAFE_PD;
_ad9510_regs.output_level_lvpecl_out0 = ad9510_regs_t::OUTPUT_LEVEL_LVPECL_OUT0_810MV;
_ad9510_regs.divider_low_cycles_out0 = 0;
_ad9510_regs.divider_high_cycles_out0 = 0;
_ad9510_regs.bypass_divider_out0 = 1;
this->write_reg(0x3c);
this->write_reg(0x48);
this->write_reg(0x49);
}
/*!
* If we are to use an external reference, enable the charge pump.
* \param enb true to enable the CP
*/
void enable_external_ref(bool enb){
_ad9510_regs.charge_pump_mode = (enb)?
ad9510_regs_t::CHARGE_PUMP_MODE_NORMAL :
ad9510_regs_t::CHARGE_PUMP_MODE_3STATE ;
_ad9510_regs.pll_mux_control = ad9510_regs_t::PLL_MUX_CONTROL_DLD_HIGH;
_ad9510_regs.pfd_polarity = ad9510_regs_t::PFD_POLARITY_POS;
this->write_reg(clk_regs.pll_2);
this->update_regs();
}
double get_master_clock_rate(void){
return 100e6;
}
void set_mimo_clock_delay(double delay) {
//delay_val is a 5-bit value (0-31) for fine control
//the equations below determine delay for a given ramp current, # of caps and fine delay register
//delay range:
//range_ns = 200*((caps+3)/i_ramp_ua)*1.3286
//offset (zero delay):
//offset_ns = 0.34 + (1600 - i_ramp_ua)*1e-4 + ((caps-1)/ramp)*6
//delay_ns = offset_ns + range_ns * delay / 31
int delay_val = boost::math::iround(delay/9.744e-9*31);
if(delay_val == 0) {
switch(clk_regs.exp) {
case 5:
_ad9510_regs.delay_control_out5 = 1;
break;
case 6:
_ad9510_regs.delay_control_out6 = 1;
break;
default:
break; //delay not supported on U2 rev 3
}
} else {
switch(clk_regs.exp) {
case 5:
_ad9510_regs.delay_control_out5 = 0;
_ad9510_regs.ramp_current_out5 = ad9510_regs_t::RAMP_CURRENT_OUT5_200UA;
_ad9510_regs.ramp_capacitor_out5 = ad9510_regs_t::RAMP_CAPACITOR_OUT5_4CAPS;
_ad9510_regs.delay_fine_adjust_out5 = delay_val;
this->write_reg(0x34);
this->write_reg(0x35);
this->write_reg(0x36);
break;
case 6:
_ad9510_regs.delay_control_out6 = 0;
_ad9510_regs.ramp_current_out6 = ad9510_regs_t::RAMP_CURRENT_OUT6_200UA;
_ad9510_regs.ramp_capacitor_out6 = ad9510_regs_t::RAMP_CAPACITOR_OUT6_4CAPS;
_ad9510_regs.delay_fine_adjust_out6 = delay_val;
this->write_reg(0x38);
this->write_reg(0x39);
this->write_reg(0x3A);
break;
default:
break;
}
}
}
private:
/*!
* Write a single register to the spi regs.
* \param addr the address to write
*/
void write_reg(boost::uint8_t addr){
boost::uint32_t data = _ad9510_regs.get_write_reg(addr);
_iface->write_spi(SPI_SS_AD9510, spi_config_t::EDGE_RISE, data, 24);
}
/*!
* Tells the ad9510 to latch the settings into the operational registers.
*/
void update_regs(void){
_ad9510_regs.update_registers = 1;
this->write_reg(clk_regs.update);
}
//uses output clock 3 (pecl)
//this is the same between USRP2 and USRP2+ and doesn't get a switch statement
void enable_dac_clock(bool enb){
_ad9510_regs.power_down_lvpecl_out3 = (enb)?
ad9510_regs_t::POWER_DOWN_LVPECL_OUT3_NORMAL :
ad9510_regs_t::POWER_DOWN_LVPECL_OUT3_SAFE_PD;
_ad9510_regs.output_level_lvpecl_out3 = ad9510_regs_t::OUTPUT_LEVEL_LVPECL_OUT3_810MV;
_ad9510_regs.bypass_divider_out3 = 1;
this->write_reg(clk_regs.output(clk_regs.dac));
this->write_reg(clk_regs.div_hi(clk_regs.dac));
this->update_regs();
}
//uses output clock 4 (lvds) on USRP2 and output clock 2 (lvpecl) on USRP2+
void enable_adc_clock(bool enb){
switch(clk_regs.adc) {
case 2:
_ad9510_regs.power_down_lvpecl_out2 = enb? ad9510_regs_t::POWER_DOWN_LVPECL_OUT2_NORMAL : ad9510_regs_t::POWER_DOWN_LVPECL_OUT2_SAFE_PD;
_ad9510_regs.output_level_lvpecl_out2 = ad9510_regs_t::OUTPUT_LEVEL_LVPECL_OUT2_500MV;
_ad9510_regs.bypass_divider_out2 = 1;
break;
case 4:
_ad9510_regs.power_down_lvds_cmos_out4 = enb? 0 : 1;
_ad9510_regs.lvds_cmos_select_out4 = ad9510_regs_t::LVDS_CMOS_SELECT_OUT4_LVDS;
_ad9510_regs.output_level_lvds_out4 = ad9510_regs_t::OUTPUT_LEVEL_LVDS_OUT4_1_75MA;
_ad9510_regs.bypass_divider_out4 = 1;
break;
}
this->write_reg(clk_regs.output(clk_regs.adc));
this->write_reg(clk_regs.div_hi(clk_regs.adc));
this->update_regs();
}
usrp2_iface::sptr _iface;
usrp2_clk_regs_t clk_regs;
ad9510_regs_t _ad9510_regs;
};
/***********************************************************************
* Public make function for the ad9510 clock control
**********************************************************************/
usrp2_clock_ctrl::sptr usrp2_clock_ctrl::make(usrp2_iface::sptr iface){
return sptr(new usrp2_clock_ctrl_impl(iface));
}