SLWS230E September 2011 – December 2015
PRODUCTION DATA.
The TRF3765 device features a four-wire serial programming interface (4WI) that controls an internal 32-bit shift register. There are a total of three signals that must be applied: the clock (CLOCK, pin 4), the serial data (DATA, pin 3); and the latch enable (STROBE, pin 5).
The serial data (DB0-DB31) are loaded least significant bit (LSB) first, and read on the rising edge of CLOCK. STROBE is asynchronous to the CLOCK signal, at its rising edge, the data in the shift register are loaded into the selected internal register. Figure 1 shows the timing for the 4WI. 4WI Timing: Write Operation lists the 4WI timing for the write operation.
The lock detect signal is generated in the phase frequency detector by comparing the VCO target phase against the VCO actual phase. When the two compared phase signals remain aligned for several clock cycles, an internal signal goes high. The precision of this comparison is controlled through the LD_ANA_PREC bits. This internal signal is then averaged and compared against a reference voltage to generate the LD signal. The number of averages used is controlled through LD_DIG_PREC. Therefore, when the VCO is frequency locked, LD is high. When the VCO frequency is not locked, LD may pulse high or exhibit periodic behavior.
By default, the internal lock detect signal is made available on the LD pin. Register bits MUX_CTRL_n can be used to control a multiplexer to output other diagnostic signals on the LD output. The LD control signals are shown in Table 2. Table 3 shows the LD Control Signal Mode settings.
ADJUSTMENT | REGISTER BITS | BIT ADDRESSING |
---|---|---|
Lock detect precision | LD_ANA_PREC_0 | Reg4B19 |
Unlock detect precision | LD_ANA_PREC_1 | Reg4B20 |
LD averaging count | LD_DIG_PREC | Reg4B24 |
Diagnostic output | MUX_CTRL_n | Reg6B[18..16] |
CONDITION | RECOMMENDED SETTINGS |
---|---|
Integer mode | LD_ANA_PREC_0 = 0 LD_ANA_PREC_1 = 0 LD_DIG_PREC = 0 |
Fractional mode | LD_ANA_PREC_0 = 1 LD_ANA_PREC_1 = 1 LD_DIG_PREC = 0 |
The LO divider is shown in Figure 66. It frequency divides the VCO output. Only one of the dividers operates at a time, and the appropriate output is selected by a mux. DIVn bits are controlled through LO_DIV_SEL_n. The output is buffered and provided on output pins LOn_OUT_P and LOn_OUT_N. Outputs are phase-locked but not phase-matched. The output level is controlled through BUFOUT_BIAS.
LO_DIV_IB determines the bias level for the divider blocks. The SPEEDUP control is used to bypass a stabilization resistor and reach the final bias level faster after a change in the divider selection. SPEEDUP should be disabled during normal operation.
To achieve a broad frequency tuning range, the TRF3765 includes four VCOs. Each VCO is connected to a bank of coarse tuning capacitors that determine the valid operating frequency of each VCO. For any given frequency setting, the appropriate VCO and capacitor array must be selected.
The device contains logic that automatically selects the appropriate VCO and capacitor bank. Set bit EN_CAL to initiate the calibration algorithm. During the calibration process, the device selects a VCO and a tuning capacitor state such that VTUNE matches the reference voltage set by VCO_CAL_REF_n. Accuracy of the resulting tuning word is increased through bits CAL_ACC_n at the expense of increased calibration time. A calibration begins immediately when EN_CAL is set; as a result, all registers must contain valid values before a calibration is initiated.
The calibration logic is driven by a CAL_CLK clock derived from the phase frequency detector frequency scaled according to the setting in CAL_CLK_SEL. Faster CAL_CLK frequencies enable faster calibrations, but the logic is limited to clock frequencies up to 600 kHz. The flag R_SAT_ERR is evaluated during the calibration process to indicate calibration counter overflow errors, which occur if CAL_CLK runs too quickly. If R_SAT_ERR is set during a calibration, the resulting calibration is not valid and CAL_CLK_SEL must be used to slow the CAL_CLK. CAL_CLK frequencies should not be set below 0.05 MHz. Reference clock frequency is usually limited by the calibration logic. fREF × CAL_CLK_SEL scaling factor > 0.01 MHz and fREF/(CAL_CLK_SEL scaling factor × fPFD) < 8000 are required. For example, with fREF = 61.44 MHz, fPFD = 30.72 MHz and CAL_CLK_SEL at 1/128, 61.44/128 = 0.5 > 0.01 and 61.44/(30.72 × 1/128) = 256 < 8000.
When VCOSEL_MODE is 0, the device automatically selects both the VCO and capacitor bank within 46 CAL_CLK cycles. When VCOSEL_MODE is 1, the device uses the VCO selected in VCO_SEL_0 and VCO_SEL_1 and automatically selects the capacitor array within 34 CAL_CLK cycles. The VCO and capacitor array settings that result from a calibration cannot be read from the VCO_SEL_n and VCO_TRIM_n bits in Registers 2 and 7. These settings can only be read from Register 0.
Automatic calibration can be disabled by setting CAL_BYPASS to 1. In this manual calibration mode, the VCO is selected through register bits VCO_SEL_n, while the capacitor array is selected through register bits VCO_TRIM_n. Calibration modes are summarized in Table 4. After calibration is complete, the PLL is released from calibration mode and reaches phase lock.
CAL_BYPASS | VCOSEL_MODE | MAX CYCLES CAL_CLK | VCO | CAPACITOR ARRAY |
---|---|---|---|---|
0 | 0 | 46 | Automatic | |
0 | 1 | 34 | VCO_SEL_n | Automatic |
1 | don't care | N/A | VCO_SEL_n | VCO_TRIM_n |
During the calibration process, the TRF3765 scans through many frequencies. RF and LO outputs should be disabled until calibration is complete. At power-up, the RF and LO output are disabled by default. Once a calibration has been performed at a given frequency setting, the calibration remains valid over all operating temperature conditions.
An external LO or VCO signal may be applied. EN_EXTVCO powers the input buffer and selects the buffered external signal instead of an internal VCO. Dividers, phase-frequency detector, and charge pump remain enabled and may be used to control VTUNE or an external VCO. NEG_VCO must correspond to the sign of the external VCO tuning characteristic. EXT_VCO_CTRL = 1 asserts a logic 1 output level at the corresponding output pin. This configuration can be used to enable or disable the external VCO circuit or module.
Setting VCO_TEST_MODE forces the currently selected VCO to the edge of its frequency range by disconnecting the charge pump input from the phase detector and loop filter, and forcing its output high or low. The upper or lower edge of the VCO range is selected through COUNT_MODE_MUX_SEL.
VCO_TEST_MODE also reports the value of a frequency counter in COUNT, which can be read back in Register 0. COUNT reports the number of digital N divider cycles in the PLL, directly related to the period of fN, that occur during each CAL_CLK cycle. Counter operation is initiated through the bit EN_CAL. Table 5 summarizes the settings for VCO_TEST_MODE.
VCO_TEST_MODE | COUNT_MODE_MUX_SEL | VCO OPERATION | REGISTER 0 B[30..13] |
---|---|---|---|
0 | Don't care | Normal | B[30..24] = undefined B[23..22] = VCO_SEL selected during autocal B21 = undefined B[20..15] = VCO_TRIM selected during autocal B[14..13] = undefined |
1 | 0 | Max frequency | B[30..13] = Max frequency counter |
1 | 1 | Min frequency | B[30..13] = Min frequency counter |
Register 0 functions as a readback register. The TRF3765 implements the capability to read back the content of any serial programming interface register by initializing Register 0.
Each read-back operation consists of two phases: a write followed by the actual reading of the internal data. This sequence is described in the timing diagram (see Figure 2). During the write phase, a command is sent to TRF3765 Register 0 to set it to readback mode and to specify which register is to be read. In the proper reading phase, at each rising clock edge, the internal data are transferred to the READBACK pin where it can be read at the following falling edge (LSB first). The first clock after the latch enable STROBE, pin 5, goes high (that is, the end of the write cycle) is idle and the following 32 clock pulses transfer the internal register contents to the READBACK pin (pin 6).
The PLL is designed to operate in either Integer mode or Fractional mode. If the desired local oscillator (LO) frequency is an integer multiple of the phase frequency detector (PFD) frequency, fPFD, then Integer mode can be selected. The normalized in-band phase noise floor in Integer mode is lower than in Fractional mode. In Integer mode, the feedback divider is an exact integer, and the fraction is zero. While operating in Integer mode, the register bits corresponding to the fractional control are don’t care.
In Fractional mode, the feedback divider fractional portion is non-zero on average. With 25-bit fractional resolution, RF stepsize fPFD/225 is less than 1 Hz with a fPFD up to 33 MHz. The appropriate fractional control bits in the serial register must be programmed.
Figure 67 shows a diagram of the PLL loop.
The output frequency is given by Equation 1:
The rate at which phase comparison occurs is fREF/RDIV. In Integer mode, the fractional setting is ignored and Equation 2 is applied.
The feedback divider block consists of a programmable RF divider, a prescaler divider, and an NF divider. The prescaler can be programmed as either a 4/5 or an 8/9 prescaler. The NF divider includes an A counter and an M counter.
Operation of the PLL requires the LO_DIV_SEL, RDIV, PLL_DIV_SEL, NINT, and NFRAC bits to be calculated. The LO or mixer frequency is related to fVCO according to divide-by-1/-2/-4/-8 blocks and the operating range of fVCO.
Therefore:
Given fVCO, select the minimum value for PLL_DIV_SEL so that the programmable RF divider limits the input frequency into the prescaler block, fPM, to a maximum of 3000 MHz.
PLL _ DIV _ SEL = min(1, 2, 4) such that fPM ≤ 3000 MHz
This calculation can be restated as Equation 3.
Higher values of fPFD correspond to better phase noise performance in Integer mode or Fractional mode. fPFD, along with PLL_DIV_SEL, determines the fVCO stepsize in Integer mode. Therefore, in Integer mode, select the maximum fPFD that allows for the required RF stepsize, as shown by Equation 4.
In Fractional mode, a small RF stepsize is accomplished through the Fractional mode divider. A large fPFD should be used to minimize the effects of fractional controller noise in the output spectrum. In this case, fPFD may vary according to the reference clock and fractional spur requirements; for example, fPFD = 20 MHz.
The P/(P+1) programmable prescaler is set to 8/9 or 4/5 through the PRSC_SEL bit. To allow proper fractional control, set PRSC_SEL according to Equation 5.
The PRSC_SEL limit at NINT < 75 applies to Fractional mode with third-order modulation. In Integer mode, the PRSC_SEL = 8/9 should be used with NINT as low as 72. The divider block accounts for either value of PRSC_SEL without requiring NINT or NFRAC to be adjusted. Then, calculate the maximum frequency to be input to the digital divider at fN. Use the lower of the possible prescaler divide settings, P = (4,8), as shown by Equation 6.
Verify that the frequency into the digital divider, fN, is less than or equal to 375 MHz. If fN exceeds 375 MHz, choose a larger value for PLL_DIV_SEL and recalculate fPFD, RDIV, NINT, NFRAC, and PRSC_SEL.
Suppose the following operating characteristics are desired for Integer mode operation:
The VCO range is 2400 MHz to 4800 MHz. Therefore:
To keep the frequency of the prescaler below 3000 MHz:
The desired stepsize at RF is 2 MHz, so:
Using the reference frequency along with the required fPFD gives:
NINT ≥ 75; therefore, select the 8/9 prescaler.
where
This example shows that Integer mode operation gives sufficient resolution for the required stepsize.
Suppose the following operating characteristics are desired for Fractional mode operation:
The VCO range is 2400 MHz to 4800 MHz. Therefore:
To keep the frequency of the prescaler below 3000 MHz:
Using a typical fPFD of 20 MHz:
NINT ≥ 75; therefore, select the 8/9 prescaler.
where
The actual frequency at RF is:
For a frequency error of –0.058 Hz.
Optimal operation of the PLL in Fractional mode requires several additional register settings. Recommended values are listed in Register Maps. Optimal performance may require tuning the MOD_ORD, ISOURCE_SINK, and ISOURCE_TRIM values according to the chosen frequency band.
REGISTER BIT | REGISTER ADDRESSING | RECOMMENDED VALUE |
---|---|---|
EN_ISOURCE | Reg4B18 | 1 |
EN_DITH | Reg4B25 | 1 |
MOD_ORD | Reg4B[27..26] | B[27..26] = [10] |
DITH_SEL | Reg4B28 | 0 |
DEL_SD_CLK | Reg4B[30..29] | B[30..29] = [10] |
EN_FRAC | Reg4B31 | 1 |
EN_LD_ISOURCE | Reg5B31 | 0 |
ISOURCE_SINK | Reg6B19 | 0 |
ISOURCE_TRIM | Reg6B[22..20] | B[22..20] = [100] or [111]; see Typical Characteristics |
ICPDOUBLE | Reg1B26 | 0 |
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 |
RSV | VCO CAL CLK DIV/MULT |
CP DOUBLE |
CHARGE PUMP CURRENT | VCO NEG | REF INV | RSV | REF CLOCK DIV | ||||||||
15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
REFERENCE CLOCK DIVIDER | REGISTER ADDRESS |
Set the frequency divider value used to derive the VCO calibration clock from the phase detector frequency. Table 8 shows the calibration clock scale factors.
CAL_CLK_SEL | SCALING FACTOR |
---|---|
1111 | 1/128 |
1110 | 1/64 |
1101 | 1/32 |
1100 | 1/16 |
1011 | 1/8 |
1010 | 1/4 |
1001 | 1/2 |
1000 | 1 |
0110 | 2 |
0101 | 4 |
0100 | 8 |
0011 | 16 |
0010 | 32 |
0001 | 64 |
0000 | 128 |
Set the charge pump current. Table 9 lists the charge pump current settings.
ICP[4..0] | CURRENT (mA) |
---|---|
00 000 | 1.94 |
00 001 | 1.76 |
00 010 | 1.62 |
00 011 | 1.49 |
00 100 | 1.38 |
00 101 | 1.29 |
00 110 | 1.21 |
00 111 | 1.14 |
01 000 | 1.08 |
01 001 | 1.02 |
01 010 | 0.97 |
01 011 | 0.92 |
01 100 | 0.88 |
01 101 | 0.84 |
01 110 | 0.81 |
01 111 | 0.78 |
10 000 | 0.75 |
10 001 | 0.72 |
10 010 | 0.69 |
10 011 | 0.67 |
10 100 | 0.65 |
10 101 | 0.63 |
10 110 | 0.61 |
10 111 | 0.59 |
11 000 | 0.57 |
11 001 | 0.55 |
11 010 | 0.54 |
11 011 | 0.52 |
11 100 | 0.51 |
11 101 | 0.5 |
11 110 | 0.48 |
11 111 | 0.47 |
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 |
EN CAL | CAL ACCURACY | VCO SEL MODE | VCO SELECT | RSV | RSV | PRE- SCALER SELECT |
PLL DIVIDER SETTING | N-DIVIDER VALUE | |||||||
15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
N-DIVIDER VALUE | REGISTER ADDRESS |
Bit | Field | Reset Value | Description |
---|---|---|---|
Bit0 | ADDR_0 | 0 | Register address bits |
Bit1 | ADDR_1 | 1 | |
Bit2 | ADDR_2 | 0 | |
Bit3 | ADDR_3 | 1 | |
Bit4 | ADDR_4 | 0 | |
Bit5 | NINT_0 | 0 | PLL N-divider division setting |
Bit6 | NINT_1 | 0 | |
Bit7 | NINT_2 | 0 | |
Bit8 | NINT_3 | 0 | |
Bit9 | NINT_4 | 0 | |
Bit10 | NINT_5 | 0 | |
Bit11 | NINT_6 | 0 | |
Bit12 | NINT_7 | 1 | |
Bit13 | NINT_8 | 0 | |
Bit14 | NINT_9 | 0 | |
Bit15 | NINT_10 | 0 | |
Bit16 | NINT_11 | 0 | |
Bit17 | NINT_12 | 0 | |
Bit18 | NINT_13 | 0 | |
Bit19 | NINT_14 | 0 | |
Bit20 | NINT_15 | 0 | |
Bit21 | PLL_DIV_SEL0 | 1 | Select division ratio of divider in front of prescaler |
Bit22 | PLL_DIV_SEL1 | 0 | |
Bit23 | PRSC_SEL | 1 | Set prescaler modulus (0 → 4/5; 1 → 8/9) |
Bit24 | RSV | 0 | Reserved |
Bit25 | RSV | 0 | Reserved |
Bit26 | VCO_SEL_0 | 0 | Selects between the four integrated VCOs 00 = lowest frequency VCO; 11= highest frequency VCO |
Bit27 | VCO_SEL_1 | 1 | |
Bit28 | VCOSEL_MODE | 0 | Single VCO auto-calibration mode (1 = active) |
Bit29 | CAL_ACC_0 | 0 | Error count during the cap array calibration Recommended programming [00]. |
Bit30 | CAL_ACC_1 | 0 | |
Bit31 | EN_CAL | 0 | Execute a VCO frequency auto-calibration. Set to 1 to initiate a calibration. Resets automatically. |
Select division ratio of divider in front of prescaler, according to Table 11.
PLL_DIV | FREQUENCY DIVIDER |
---|---|
00 | 1 |
01 | 2 |
10 | 4 |
When VCOSEL_MODE is set to 1, the cap array calibration is executed on the VCO selected through bits VCO_SEL[1:0].
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 |
RSV | RSV | FRACTIONAL N-DIVIDER VALUE | |||||||||||||
15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
FRACTIONAL N-DIVIDER VALUE | REGISTER ADDRESS |
Bit | Field | Reset Value | Description |
---|---|---|---|
Bit0 | ADDR_0 | 1 | Register address bits |
Bit1 | ADDR_1 | 1 | |
Bit2 | ADDR_2 | 0 | |
Bit3 | ADDR_3 | 1 | |
Bit4 | ADDR_4 | 0 | |
Bit5 | NFRAC<0> | 0 | Fractional PLL N divider value 0 to 0.99999 |
Bit6 | NFRAC<1> | 0 | |
Bit7 | NFRAC<2> | 0 | |
Bit8 | NFRAC<3> | 0 | |
Bit9 | NFRAC<4> | 0 | |
Bit10 | NFRAC<5> | 0 | |
Bit11 | NFRAC<6> | 0 | |
Bit12 | NFRAC<7> | 0 | |
Bit13 | NFRAC<8> | 0 | |
Bit14 | NFRAC<9> | 0 | |
Bit15 | NFRAC<10> | 0 | |
Bit16 | NFRAC<11> | 0 | |
Bit17 | NFRAC<12> | 0 | |
Bit18 | NFRAC<13> | 0 | |
Bit19 | NFRAC<14> | 0 | |
Bit20 | NFRAC<15> | 0 | |
Bit21 | NFRAC<16> | 0 | |
Bit22 | NFRAC<17> | 0 | |
Bit23 | NFRAC<18> | 0 | |
Bit24 | NFRAC<19> | 0 | |
Bit25 | NFRAC<20> | 0 | |
Bit26 | NFRAC<21> | 0 | |
Bit27 | NFRAC<22> | 0 | |
Bit28 | NFRAC<23> | 0 | |
Bit29 | NFRAC<24> | 0 | |
Bit30 | RSV | 0 | Reserved |
Bit31 | RSV | 0 | Reserved |
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 |
EN FRACT MODE | ΔΣ MOD CONTROLS | ΔΣ MOD ORDER | PLL TESTS CONTROL | EXT VCO | |||||||||||
15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
POWER-DOWN OUTPUT BUFFERS | POWER-DOWN PLL BLOCKS | PD PLL | REGISTER ADDRESS |
Bit | Field | Reset Value | Description |
---|---|---|---|
Bit0 | ADDR_0 | 0 | Register address bits |
Bit1 | ADDR_1 | 0 | |
Bit2 | ADDR_2 | 1 | |
Bit3 | ADDR_3 | 1 | |
Bit4 | ADDR_4 | 0 | |
Bit5 | PWD_PLL | 0 | Power-down all PLL blocks (1 = off) |
Bit6 | PWD_CP | 0 | When 1, charge pump is off |
Bit7 | PWD_VCO | 0 | When 1, VCO is off |
Bit8 | PWD_VCOMUX | 0 | Power-down the four VCO mux blocks (1 = off) |
Bit9 | PWD_DIV124 | 0 | Power-down programmable RF divider in PLL feedback path (1 = off) |
Bit10 | PWD_PRESC | 0 | Power-down programmable prescaler (1 = off) |
Bit11 | PWD_LO_DIV | 1 | Power-down LO divider block (1 = off) |
Bit12 | PWD_BUFF_1 | 1 | Power-down LO output buffer 1 (1 = off) |
Bit13 | PWD_BUFF_2 | 1 | Power-down LO output buffer 2 (1 = off) |
Bit14 | PWD_BUFF_3 | 1 | Power-down LO output buffer 3 (1 = off) |
Bit15 | PWD_BUFF_4 | 1 | Power-down LO output buffer 4 (1 = off) |
Bit16 | EN_EXTVCO | 0 | Enable external VCO input buffer (1 = enabled) |
Bit17 | EXT_VCO_CTRL | 0 | Can be used to enable/disable an external VCO through pin EXTVCO_CTRL (1 = high). |
Bit18 | EN_ISOURCE | 0 | Enable offset current at Charge Pump output (to be used in Fractional mode only; 1 = on). |
Bit19 | LD_ANA_PREC_0 | 0 | Control precision of analog lock detector 1 = low; 0 = high |
Bit20 | LD_ANA_PREC_1 | 0 | |
Bit21 | CP_TRISTATE_0 | 0 | Set the charge pump output into 3-state mode. Normal, B[22..21] = [00] Down, B[22..21] = [01] Up, B[22..21] = [10] 3-state, B[22..21] = [11] |
Bit22 | CP_TRISTATE_1 | 0 | |
Bit23 | SPEEDUP | 0 | Speed up PLL block by bypassing bias stabilizer capacitors. |
Bit24 | LD_DIG_PREC | 0 | Lock detector precision (increases sampling time if set to 1) |
Bit25 | EN_DITH | 1 | Enable ΔΣ modulator dither (1 = on) |
Bit26 | MOD_ORD_0 | 0 | ΔΣ modulator order (1 through 4). Not used in Integer mode. First order, B[27..26] = [00] Second order, B[27..26] = [01] Third order, B[27..26] = [10] Fourth order, B[27..26] = [11] |
Bit27 | MOD_ORD_1 | 1 | |
Bit28 | DITH_SEL | 0 | Select dither mode for ΔΣ modulator (0 = pseudo-random; 1 = constant) |
Bit29 | DEL_SD_CLK_0 | 0 | ΔΣ modulator clock delay. Not used in Integer mode. Min delay = 00; Max delay = 11 |
Bit30 | DEL_SD_CLK_1 | 1 | |
Bit31 | EN_FRAC | 0 | Enable Fractional mode (1 = fractional enabled) |
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 |
EN_LD ISRC |
RSV | VCO BIAS VOLTAGE | VCOMUX AMPL | VCO CAL REF | BIAS SEL | RSV | RSV | OUTBUF BIAS | VCOMUX BIAS | ||||||
15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
VCOBUF BIAS | VCO CURRENT | PLL_R_TRIM | VCO_R_TRIM | REGISTER ADDRESS |
Bit | Field | Reset Value | Description |
---|---|---|---|
Bit0 | ADDR_0 | 1 | Register address bits |
Bit1 | ADDR_1 | 0 | |
Bit2 | ADDR_2 | 1 | |
Bit3 | ADDR_3 | 1 | |
Bit4 | ADDR_4 | 0 | |
Bit5 | VCOBIAS_RTRIM_0 | 0 | VCO bias resistor trimming. Recommended programming [100]. |
Bit6 | VCOBIAS_RTRIM_1 | 0 | |
Bit7 | VCOBIAS_RTRIM_2 | 1 | |
Bit8 | PLLBIAS_RTRIM_0 | 0 | PLL bias resistor trimming. Recommended programming [10]. |
Bit9 | PLLBIAS_RTRIM_1 | 1 | |
Bit10 | VCO_BIAS_0 | 0 | VCO bias reference current. 300 μA, B[13..10] = [00 00] 600 μA, B[13..10] = [11 11] Bias current varies directly with reference current Recommended programming: 400 μA, B[13..10] = [0101] with VCC_TK = 3.3 V 600 μA, B[13..10] = [1111] with VCC_TK = 5.0V |
Bit11 | VCO_BIAS_1 | 0 | |
Bit12 | VCO_BIAS_2 | 0 | |
Bit13 | VCO_BIAS_3 | 1 | |
Bit14 | VCOBUF_BIAS_0 | 0 | VCO buffer bias reference current. 300 μA, B[15..14] = [00] 600 μA, B[15..14] = [11] Bias current varies directly with reference current Recommended programming [10] |
Bit15 | VCOBUF _BIAS_1 | 1 | |
Bit16 | VCOMUX_BIAS_0 | 0 | VCO muxing buffer bias reference current. 300 μA, B[17..16] = [00] 600 μA, B[17..16] = [11] Bias current varies directly with reference current Recommended programming [10] |
Bit17 | VCOMUX _BIAS_1 | 1 | |
Bit18 | BUFOUT_BIAS_0 | 1 | PLL output buffer bias reference current. 300 μA, B[19..18] = [00] 600 μA, B[19..18] = [11] Bias current varies directly with reference current |
Bit19 | BUFOUT_BIAS_1 | 0 | |
Bit20 | RSV | 0 | Reserved |
Bit21 | RSV | 1 | Reserved |
Bit22 | VCO_CAL_IB | 0 | Select bias current type for VCO calibration circuitry 0 = PTAT; 1 = constant over temperature. Recommended programming [0]. |
Bit23 | VCO_CAL_REF_0 | 0 | VCO calibration reference voltage trimming. 0.9 V, B[25..23] = [000] 1.4 V, B[25..23] = [111] Recommended programming 1.11 V, B[25..23] = [011] |
Bit24 | VCO_CAL_REF_1 | 0 | |
Bit25 | VCO_CAL_REF_2 | 1 | |
Bit26 | VCO_AMPL_CTRL_0 | 0 | Adjust the signal amplitude at the VCO mux input. [00] = maximum voltage swing [11] = minimum voltage swing Recommended programming [11] |
Bit27 | VCO_AMPL_CTRL_1 | 1 | |
Bit28 | VCO_VB_CTRL_0 | 0 | VCO core bias voltage control 1.2 V, B[29..28] = [00] 1.35 V, B[29..28] = [01] 1.5 V, B[29..28] = [10] 1.65 V, B[29..28] = [11] Recommended programming [01] |
Bit29 | VCO_VB_CTRL _1 | 1 | |
Bit30 | RSV | 0 | Reserved |
Bit31 | EN_LD_ISOURCE | 1 | Enable monitoring of LD to turn on ISOURCE when in frac-n mode (EN_FRAC=1). 0 = ISOURCE set by EN_ISOURCE 1 = ISOURCE set by LD Recommended programming [0] |
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 |
VCO BIAS SEL | DC OFF REF | VCO MUX BIAS | LO DIV BIAS | LO DIV | OFFSET CURRENT ADJUST | ISRC SINK | MUX CONTROL | ||||||||
15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
CAL BYPASS | VCO TEST MODE | LD MODE | VCO CAP ARRAY CONTROL | RSV | RSV | REGISTER ADDRESS |
The TRF3765 integrates eight registers: Register 0 (000) to Register 7 (111). Registers 1 through 6 are used to set up and control the TRF3765 functions, Register 7 is used for factory functions, and Register 0 is used for the readback function, as shown in Readback Mode.
Register 0 must be programmed with a specific command that sets the TRF3765 into readback mode and specifies the register to be read, according to the following parameters:
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 |
RB_ ENABLE |
RB_REG | COUNT_ MODE_ MUX_SEL |
N/C | ||||||||||||
15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
N/C | REGISTER ADDRESS |
Type | Bit | Field | Reset Value | Description |
---|---|---|---|---|
Address | Bit0 | ADDR<0> | 0 | Register 0 to be programmed to set the TRF3765 into readback mode. |
Bit1 | ADDR<1> | 0 | ||
Bit2 | ADDR<2> | 0 | ||
Bit3 | ADDR<3> | 1 | ||
Bit4 | ADDR<4> | 0 | ||
Data Field | Bit5 | N/C | 0 | |
Bit6 | N/C | 0 | ||
Bit7 | N/C | 0 | ||
Bit8 | N/C | 0 | ||
Bit9 | N/C | 0 | ||
Bit10 | N/C | 0 | ||
Bit11 | N/C | 0 | ||
Bit12 | N/C | 0 | ||
Bit13 | N/C | 0 | ||
Bit14 | N/C | 0 | ||
Bit15 | N/C | 0 | ||
Bit16 | N/C | 0 | ||
Bit17 | N/C | 0 | ||
Bit18 | N/C | 0 | ||
Bit19 | N/C | 0 | ||
Bit20 | N/C | 0 | ||
Bit21 | N/C | 0 | ||
Bit22 | N/C | 0 | ||
Bit23 | N/C | 0 | ||
Bit24 | N/C | 0 | ||
Bit25 | N/C | 0 | ||
Bit26 | N/C | 0 | ||
Bit27 | COUNT_MODE_MUX_SEL | 0 | Select Readback for VCO maximum frequency or minimum frequency. 0 = Maximum 1 = Minimum |
|
Bit28 | RB_REG<0> | X | Three LSBs of the address for the register that is being read Register 1, B[30..28] = [000] Register 7, B[30..28] = [111] |
|
Bit29 | RB_REG<1> | X | ||
Bit30 | RB_REG<2> | X | ||
Bit31 | RB_ENABLE | 1 | 1 → Put the device into readback mode |
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 |
COUNT MODE MUX_SEL |
COUNT11-17 | COUNT9-10/VCO_SEL | COUNT8/ NU |
COUNT0-7/VCO_TRIM | |||||||||||
15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
COUNT0-7/VCO_TRIM | R_SAT_ERR | NOT USED | CHIP_ID | REGISTER ADDRESS |
Bit | Field | Reset Value | Description |
---|---|---|---|
Bit0 | ADDR_0 | 0 | Register address bits |
Bit1 | ADDR_1 | 0 | |
Bit2 | ADDR_2 | 0 | |
Bit3 | ADDR_3 | 1 | |
Bit4 | ADDR_4 | 0 | |
Bit5 | CHIP_ID | 1 | |
Bit6 | NU | x | |
Bit7 | NU | x | |
Bit8 | NU | x | |
Bit9 | NU | x | |
Bit10 | NU | x | |
Bit11 | NU | x | |
Bit12 | R_SAT_ERR | x | Error flag for calibration speed |
Bit13 | count_0/NU | x | B[30..13] = VCO frequency counter high when COUNT_MODE_MUX_SEL = 0 and VCO_TEST_MODE = 1 B[30..13] = VCO frequency counter low when COUNT_MODE_MUX_SEL = 1 and VCO_TEST_MODE = 1 B[20..15] = Autocal results for VCO_TRIM B[23..22] = Autocal results for VCO_SEL when VCO_TEST_MODE = 0 |
Bit14 | count_1/NU | x | |
Bit15 | count_2/VCO_TRIM_0 | x | |
Bit16 | count_3/VCO_TRIM_1 | x | |
Bit17 | count_4/VCO_TRIM_2 | x | |
Bit18 | count_5/VCO_TRIM_3 | x | |
Bit19 | count_6/VCO_TRIM_4 | x | |
Bit20 | count_7/VCO_TRIM_5 | x | |
Bit21 | count_8/NU | x | |
Bit22 | count_9/VCO_sel_0 | x | |
Bit23 | count_10/VCO_sel_1 | x | |
Bit24 | count<11> | x | |
Bit25 | count<12> | x | |
Bit26 | count<13> | x | |
Bit27 | count<14> | x | |
Bit28 | count<15> | x | |
Bit29 | count<16> | x | |
Bit30 | count<17> | x | |
Bit31 | COUNT_MODE_MUX_SEL | x | 0 = Minimum frequency 1 = Maximum frequency |