HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 0-1 Features • Fractional or Integer Modes • Low Fractional Spurious • 8 GHz, 16-Bit RF N-Counter • Reference spurs: -90 dBc typ • 24-Bit Step Size Resolution, 3 Hz typ • Auto and Triggered Sweeper Functions • Ultra Low Phase Noise 6 GHz, 50 MHz Ref. -103 / -110 dBc/Hz @ 20 kHz (Frac / Integer) • Cycle Slip Prevention (CSP) for fast settling • Auxiliary Clock Source • Reference Path Input: 200 MHz • 40 Lead 6x6 mm SMT Package: 36 mm² • 14-Bit Reference Path Divider Typical Applications • Base Stations for Mobile Radio (GSM, PCS, DCS, CDMA, WCDMA) • CATV Equipment • Wireless LANs, WiMax • Automotive Radar • Communications Test Equipment • Phased-Array Systems • FMCW Sensors Functional Diagram For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL The HMC701LP6CE is a SiGe BiCMOS fractional-N PLL. The PLL includes a 8GHz 16-bit RF N-Divider, a 24-bit deltasigma modulator, a very low noise digital phase frequency detector (PFD), and a precision controlled charge pump. The fractional-N PLL features an advanced delta-sigma modulator design that allows ultra-fine frequency step sizes. The fractional-N PLL features the ability to alter both the phase-frequency detector (PFD) gain and the cycle slipping characteristics of the PFD. This feature can reduce the time to arrive at the new frequency by 50% vs. conventional PFDs. Ultra low in-close phase noise also allows wider loop bandwidths for faster frequency hopping. The fractional-N PLL contains a built-in linear sweeper function, which allows it to perform frequency chirps with a wide variety of sweep times, polarities and dwells, all with an external or automatic sweep trigger. In addition the fractional-N PLL has a number of auxiliary clock generation modes that can be accessed via the GPO. Electrical Specifications, TA = +25°C PLL - Fractional-N - SMT 0 General Description VCCHF = VCCPRS = RVDD = +3.3V VPPCP = VCCOA = VDDPDR = VPPDRV = VDDPD = VDDPDV = +5V DVDD = DVDDIO = DVDDQ = +3.3V GNDDRV = GNDCP = GNDPD = GNDPDV = GNDPDR = 0V Table 1. Electrical Specifications Parameter Conditions / Notes Min Typ Max RF Input Frequency (3.3V) 8 9 Max RF Input Frequency (2.7 - 3.3V) 7 8 Max Units Prescaler Characteristics GHz GHz Min RF Input Frequency 0.1 RF Input Power -10 16-bit N-Divider Range (Integer) 32 65,535 35 65,531 16-bit N-Divider Range (Fractional) Fraction Nominal Divide ratio varies (-3 / +4) dynamically max MHz -6 10 dBm REF Input Characteristics Max Ref Input Frequency (pin XREFP) 250 200 MHz Max Ref Input Frequency (pin XSIN) 250 220 MHz Min Ref Input Frequency Ref Input Voltage Range (pin XREFP) Ref Input Power Range (pin XSIN) 50 Ω Source. XSIN minimum 20MHz due to phase noise degradation 100 AC Coupled 750 1000 3300 mVpp -6 0 12 dBm 5 pF Ref Input Capacitance 14-Bit R-Divider Range 1 kHz 16,383 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0-2 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 1. Electrical Specifications (Continued) PLL - Fractional-N - SMT Parameter Conditions / Notes Min Typ Max Units 0.1 70 MHz 0.1 100 MHz Phase Detector Fractional Mode Phase Detector Frequency Integer Mode Phase Detector Frequency Charge Pump Max Output Current 4 mA Min Output Current 125 µA Charge Pump Gain Step Size (5-bits) 125 µA Charge Pump Trim Step Size (3-bits) 14 µA Charge Pump Offset Step Size (4-bits) 29 µA PFD / Charge Pump Noise (Integer) 6 GHz, 50 MHz Ref, Input referred 1 kHz -141 dBc/Hz 10 kHz -149 dBc/Hz 100 kHz -155 dBc/Hz Less than 3 dB degradation typ. at these limits Compliance Voltage -406 µA Offset 0.4 VPPCP-0.8 V -406 µA Offset 0.8 VPPCP-0.4 V Logic Inputs VIH Input High Voltage V VDDIO-0.4 VIL Input Low Voltage 0.4 V 0.1 V Logic Outputs VIH Output High Voltage V VDDIO-0.1 VIL Output Low Voltage Power Supply Voltages VCC - Analog 3V Supplies VCCPRS, RVDD, VCCHF 3 3.3 3.45 V DVDD, DVDDQ 3 3.3 3.45 V DVDDIO 1.8 3.3 5.5 V VCCOA, VPPCP, VPPDRV, VDDPD, VDDPDV, VDDPDR 4.5 5.0 5.5 V DVDD - Digital Internal Supply DVDDIO - Digital I/o Supply Analog 5V Supplies Power Supply Current (6 GHz Fractional Mode, 50 MHz PFD) VCCOA, VPPCP, VPPDRV, VDDPD, VDDPDV, VDDPDR 37 mA Analog +3.3V VCCPRS, RVDD, VCCHF 71 mA Digital +3.3V DVDD, DVDDIO, DVDDQ 19 mA Reg 01h = 0 Crystal not clocked 6 µA Reg 01h = 0 Crystal clocked 100 MHz 20 Analog +5V Power Down - Crystal Off Power Down - Crystal On, 100 MHz 0-3 200 µA For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 (Continued) Parameter Conditions / Notes Min Typ Max Units Temperature Sensor (3-bit) Min Temperature Readout: 000 -32 Max Temperature Readout: 111 +82 °C Temp Change / LSB 17.5 °C/LSB Worst Case Absolute Temp Error ±10 °C 2 mA 700 mV Current Consumption (when Enabled) °C Power on Reset Typical Reset Voltage on DVDD Min DVDD Voltage for No Reset 1.5 V Closed Loop Phase Noise 6 GHz VCO, Integer, 50 MHz PFD 1 kHz offset -98 dBc/Hz 6 GHz VCO, Integer, 50 MHz PFD 10 kHz offset -108 dBc/Hz 6 GHz VCO, Integer, 50 MHz PFD 100 kHz offset -110 dBc/Hz 1 kHz offset -93 dBc/Hz 6 GHz VCO, Fractional, 50 MHz PFD 6 GHz VCO, Fractional, 50 MHz PFD 10 kHz offset -103 dBc/Hz 6 GHz VCO, Fractional, 50 MHz PFD 100 kHz offset -105 dBc/Hz Closed Loop Phase Noise Normalized to 1 Hz Integer Mode Measured with 50 MHz PFD -227 dBc/Hz Fractional Mode Measured with 50 MHz PFD -221 dBc/Hz PLL - Fractional-N - SMT Table 1. Electrical Specifications Table 2. Absolute Maximum Ratings Parameter Rating RVDD, VCCHF, DVDD, DVDDQ, VCCPRS -0.3 to +3.6V VCCOA, VPPCP, VPPDRV, VDDPD, VDDPDV, VDDPDR, DVDDIO -0.3 to +6V Operating Temperature -40 to +85 °C Storage Temperature -65 to +120 °C Maximum Junction Temperature +125 °C Thermal Resistance (Rth) 20°C/W Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Reflow Soldering Peak Temperature 260 °C Time at Peak Temperature 40 sec ESD Sensitivity (HBM) Class 1B For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0-4 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 0-5 Table 3. Pin Description Pin No. Pin Name PIn Type 1 VCCPRS Supply Description RF Prescaler Power Supply. Nominally +3.3V 2 VCCOA Supply ChargePump OpAmp Power Supply. Nominally +5V 3 VPPCP Supply Power Supply for Charge Pump. Nominally +5V 4 CP Analog O/P Charge Pump output 5 GNDCP GND Power Supply GND for Charge Pump 6 GNDDRV GND Charge Pump GND 7 VPPDRV Supply Power supply for Charge Pump, Nominally +5V 8 VDDPD Supply Power Supply for Phase Detectors, Nominally +5V 9 GNDPD GND Power Supply GND for Phase Detector 10, 20, 21, 26 N/C N/C No Connection 11 VDDPDV Supply 12 GNDPDV GND 13 VDDPDR Supply 14 GNDPDR GND 15 XREFP Analog I/P 16 RVDD Supply 17 XSIN Analog I/P 18 REFCAP Analog I/O Reference Path bypass 19 RSTB CMOS I/P Reset Input (active low) 22 DVDD Supply Digital Power Supply, Nominally +3.3V 23 GPO1 DO General Purpose Output 1 with Tristate 24 GPO2 DO General Purpose Output 2 with Tristate 25 GPO3 DIO General Purpose Input/Output with Tristate may be configured for External Ramp trigger Input. See register REG 14h[5] 27 SEN CMOS I/P Main Serial port enable input 28 SDI CMOS I/P Main Serial port data input Main Serial port clock input Power Supply for Phase Detector VCO Path, Nominally +5V Power Supply GND for Phase Detector VCO Path Power Supply for Phase Detector Ref Path, Nominally +5V Power Supply GND for Phase Detector Ref Path Square Wave Crystal Ref Input Power Supply for Ref Path, Nominally +3.3V Sinusoidal Crystal reference input 29 SCK CMOS I/P 30 VSLE DO Leave pin disconnected. 31 VSDO DO Leave pin disconnected. 32 VSCK DO 33 LD_SDO CMOS O/P Leave pin disconnected. 34 DVDDIO Supply Power Supply for digital I/O, matches external Digital Supply in 1.8V to 5.5V range 35 DVDD Supply Internal Digital Power Supply. Nominally 3.3V 36 DVDDQ Supply Power Supply Isolation pin. Nominally 3.3V, bypassed to GND, zero current. 37 VCOIP RF I/P Complementary Input to the RF Prescaler. If single ended input, this point must be decoupled to the ground plane with a ceramic bypass capacitor, typically 100 pF 38 VCOIN RF I/P Input to the RF Prescaler. This signal input is ac-coupled to the external VCO 39 VCCHF Supply RF Section Power Supply. Nominally 3.3V 40 BIAS Analog I/P Lock Detect or Main Serial Port Data Output Decoupling Pin for RF section, nominally external 1nF bypassed to VCCHF For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL Typical Phase Noise - Fractional Mode -90 -90 6 GHz Integer -100 PHASE NOISE (dBc/Hz) PHASE NOISE (dBc/Hz) -110 1 GHz Integer -120 -130 -140 All Plots 50 MHz PFD -150 6 GHz Fractional -100 2 GHz Integer -160 2 GHz Fractional -110 -120 -130 All Plots 50 MHz PFD -140 -150 -160 -170 1000 10 4 10 5 10 6 10 7 10 -170 1000 8 4 5 10 6 7 10 10 FREQUENCY (Hz) FREQUENCY (Hz) RF Divider Sensitivity 8 10 10 Frequency Sweep 6150 20 +85C FRAC INTEG 6100 +25C 0 FREQUENCY (MHz) INPUT POWER (dBm) 10 -40C -10 -20 6050 6000 5950 5900 -30 -40 0 PLL - Fractional-N - SMT Typical Phase Noise - Integer Mode 0 2000 4000 6000 FREQUENCY (MHz) 8000 5850 -2 10000 -1 0 1 2 3 TIME (ms) Cycle Slip Prevention: Frequency Hop from 5200 MHz to 3950 MHz 5300 FREQUENCY (MHz) 5100 4900 CSP OFF 4700 4500 CSP ON 4300 4100 3900 -10 0 10 20 30 40 50 60 70 TIME (μs) For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0-6 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Theory of Operation PLL - Fractional-N - SMT The HMC701LP6CE synthesizer consists of the following functional blocks 1. Reference Path Input Buffers 2. Reference Path Divider 3. VCO Path Input Buffer 4. VCO Path Multi-Modulus Prescaler/Divider 5. Δ∑ Fractional Modulator 6. Phase Frequency Detector 7. Charge Pump 8. Main Serial Port 9. VCO Serial Port for Stepped VCO Support 10. Temperature Sensor 11. Power On Reset Circuit 12. CW Sweeper Subsystem 13. Auxiliary Clock Generator 14. General Purpose Output (GPO) Bus 15. Multiple VCO Controller Each of these blocks is described briefly in the following section. Reference Path The full Reference Path block diagram is shown in Figure 1 The ultra low noise phase detector requires the best possible reference signal. Since a given application may desire to use a square wave or a 50 Ohm sinusoidal crystal source, HMC701LP6CE offers two input ports, each one optimized for the lowest possible noise for the source type being used. For absolute best low noise performance, the sine wave path should be used. The user should use only one Ref path input, that is the input that matches their reference source type. Note the input is defaulted to the square wave input on power up. Should the sine reference path be used, it is necessary to enable the sine input, shut down the square wave input and set the mux (rfp_buf_sin_en=1, rfp_buf_sq_en=0, rfp_buf_sin_ sel=1, Table 12). The unused port should be left open. The reference path supports input frequencies of up to 250 MHz typical, however the maximum frequency at the phase detector (PFD) depends upon the mode of operation, worst case at +85°C, 70 MHz in fractional mode and 100 MHz in integer mode. Hence reference inputs of greater than the PFD maximum frequency must use the appropriate R divider setting. Figure 1. Reference Sine Input Stages The unused reference port is normally not connected. 0-7 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL The crystal reference sine input stage is shown in Figure 2. This is the lowest noise reference path. This is a common emitter single ended bipolar buffer. The XSIN input pin is DC coupled and has about 950 mV bias on it. Expected input is a 0 dBm sinusoid from a 50 Ohm source. Normally the input should be AC coupled externally. The sine buffer input impedance is dominated by a 25 Ohm shunt resistor in series with a 50 pF on chip cap. Should a lower input impedance be needed, an external 50 Ohm shunt resistor can be used, DC isolated by an external bypass cap. The sine input reference path phase noise floor is approximately equivalent to -159 dBc/Hz. For best performance care should be taken to provide a crystal reference source with equivalent or better phase noise floor. PLL - Fractional-N - SMT 0 Sine Reference Input Figure 2. Ref Sine Input Square Wave Reference Input The square wave Ref Input stage is shown in Figure 3. The stage is designed to accept square wave inputs from CML to CMOS levels. Slightly degraded phase noise performance may be obtained with quasi sine 1 Vpp inputs. It may be necessary to attenuate very large CMOS levels if absolute best in close phase noise performance is required. Input reference should have a noise floor better than -160 dBc/Hz to avoid degradation of the input reference path. Figure 3. Square Wave Ref Input Stage For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0-8 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 Reference Path ’R’ Divider The referenced path features a 14-bit divider (rfp_div_ratio, Reg03h<13:0> Table 14) and can divide input signals at up to 250 MHz by numbers from 1 to 16,383. The selected input reference source may be divided or bypassed (rfp_div_select), and applied to the phase detector reference input. Reference Path Test Features A fractional synthesizer is a complex combination of a low phase noise analog oscillator running in close proximity with a nearly randomly modulated delta-sigma digital modulator. Clean spur free operation of the synthesizer requires proper board layout of power and grounds. Spurious sources are often difficult to identify and may be related to harmonics of the digital modulation which land near the operating frequency of the VCO, or they may arise from repeating patterns in the digital modulation itself . The loop filter and the fractional modulator are designed to suppress these fractional spurs, but it is sometimes the case that the isolation of the spurious products comes from layout issues. The problem is how to identify the sources of spurious products if they occur? The reference path of the HMC701LP6CE features some interesting test options for clocking the digital portion of the synthesizer which may provide for a better understanding of the source of reference spurs should they occur. See Figure 4, Table 12 and Table 29 for more register details. It is possible for example to set the synthesizer to integer mode of operation, where the digital harmonics normally fall directly on the VCO frequency. We might chose for example to use the sine source (rfp_buf_sine_sel=1, div_ todig_en=0) to drive the reference divider. In such a case the delta sigma modulator is not normally used, however if we wish to test the effects of the digital power supply isolation, we could input a 2nd reference source on the square wave input, enable its buffer (rfp_buf_sq_en=1), and enable the 2nd crystal to clock the unused delta sigma modulator (sqr_todig_en=1 and dsm_xref_sin_select=0). This would allow the square wave clock to be set independently of the locked integer mode VCO, and hence measure the coupling of the digital to the sidebands of the VCO at various frequencies. Such a test can help in identifying and debugging grounding and layout issues in the application circuit related to the digital portion of the PCB should they occur. In general it is recommended to follow the suggested layout closely to avoid any such problems. Figure 4. Reference Path Block Diagram VCO Path The RF path from the VCO to the phase detector, is referred to as the VCO path. The VCO path consists of an input isolation buffer and a multi-modulus prescaler, or simply the N divider. The N divider is controlled by the fractional modulator. This path operates with inputs directly from the external VCO. 0-9 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL The synthesizer RF input stage routes the external VCO to the phase detector via a 16-bit fractional divider. The RF input path is rated to operate nominally from 100 kHz to 8 GHz in fractional and 9 GHz in integer modes. The RF input stage also provides isolation between the VCO and the prescaler. The RF input stage is a differential common emitter stage, DC coupled for maximum flexibility. The input is protected by ESD diodes as shown in Figure 5. Normally the RF input is AC coupled to a single ended external source. The RFINP buffer is well matched from a single ended 50 Ohm source above about 3.5 GHz, with the complimentary input grounded. If a better match is required at low frequency a simple shunt 50 Ohm resistor can be used external to the package. If a differential external source is used then the two input pins may be used for best performance. PLL - Fractional-N - SMT 0 RF Input Stage Figure 5. RF Input Stage RF Path ’N’ Divider The main RF path divider is capable of average divide ratios between 65,531 and 36 in fractional mode, and 65,535 to 32 in integer mode. The reason for the difference between integer and fractional modes is that the fractional divider actually divides by up to ±4 from the average divide number. Actual division ratios when used with a given VCO will depend upon the reference frequency used and the desired output band. General Purpose Output (GPO) Interface The HMC701LP6CE features a 3-wire General Purpose Output (GPO) interface. GPO registers are described in Reg1Bh Table 37. The GPO is a flexible interface that supports a number of different functions and real time waveform access including: a. General Data Output from SPI register gpo_sel_0_ data (gpo_sel=0) e. Internal synchronized frac strobe with clocks (gposel=4) b. Prescaler & reference path outputs (gpo_sel=1) f. Δ∑ Modulator Phase Accumulator (gposel=6) c. Lock Detect Windows (gpo_sel=2) g. Auxiliary oscillators (gposel=7) d. Anti-cycle Slip waveforms (gpo_sel=3) h. Δ∑ Modulator Outputs (gposel=10) General Data to GPO (gpo_sel=0) Setting register gpo_sel=0 in Table 37 assigns the 3-bit data from register gpo_sel_0_data Reg1B<6:4> to the GPO bus. For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 10 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 Prescaler and Reference Path Outputs (gpo_sel = 1) Setting register gpo_sel=1 (Reg1B<3:0> Table 37) results in the input crystal being buffered out to GPO3 as shown in Figure 6. This is useful for example to generate a copy of the input crystal signal to drive other circuits in the application, while at the same time isolating the noisy circuits from the sensitive crystal output. Often only the synthesizer requires very low phase noise from the crystal, hence it is desirable to isolate other circuits from the crystal itself and allow the synthesizer sole use of the low phase noise crystal. gpo_sel=1 also routes the 250 MHz 14-bit reference path divider to GP02 and the 16-bit 7 GHz VCO path prescaler output to GP01. This option allows the synthesizer to function as a stand alone fractional or integer prescaler and provides visibility into the prescaler and reference path timing for sensitive applications. Figure 6. gpo_01 Outputs Lock Detect Windows (gpo_sel=2) Setting register gpo_sel = 2 (Reg1Bh<3:0> Table 37) results in the lock detect window (Figure 11) and the phase frequency detector UP and DN output control signals (Figure 14) to be routed to pins GPO1, GPO3 and GPO2 respectively. This option gives insight into the Lock Detection Process and could allow the synthesizer to be used with an external charge pump. Figure 7. gpo_02 Outputs 0 - 11 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL Setting register gpo_sel=3 (Reg1Bh<3:0> Table 37) gives visibility into the anti-cycle slipping function of the PFD as described in section Cycle Slip Prevention (CSP). Three waveforms, reference path freq > VCO path freq, vco path freq > ref path freq, and a PFD strobe which holds the PFD at maximum gain, are routed to GPO3, GPO2, and GPO1 respectively. These lines will be active during frequency pull-in and will indicate instantaneously which signal, reference or vco path is greater in frequency. The PFD strobe gives insight into when the PFD is near maximum gain at 2π. The PFD strobe will be active until the VCO pulls into lock. Internal Synchronized Frac strobe with clocks (gpo_sel= 4) Setting register gpo_sel=4 in (Reg1Bh<3:0> Table 37) gives visibility into the internally synchronized strobe that is generated when commanding a frequency change by writing to the frac register. The internal strobe initiates the update to the fractional modulator. The internal frac strobe, the ref path divider output and the sine reference input are buffered out to GPO1,GPO2 and GPO3 respectively as shown in Figure 8. In this mode, GPO1 may be used to trigger an external instrument when doing frequency hopping tests for example. 0 PLL - Fractional-N - SMT Anti-cycle Slip Waveforms (gpo_sel = 3) Figure 8. gpo_04 Outputs Δ∑ Modulator Phase Accumulator (gpo_sel=6) Setting register gpo_sel=6 (Reg1Bh<3:0> Table 37) assigns the three msb’s of the delta sigma modulator first accumulator to GPO<3:1>, where GPO3 is the msb. This feature provides insight into the phase of the VCO. Auxiliary Oscillators (gpo_sel=7) Setting register gpo_sel=7 (Reg1Bh<3:0> Table 37) assigns an auxiliary clock, an internal ring oscillator, and the internal sigma delta clock to GPO3, 2, 1 respectively. The control of the auxiliary clock is determined by Reg18h Table 34 and Reg19h Table 35. In general terms, this highly flexible clock source allows the selection of one of the various VCO or crystal related clocks inside the synthesizer or the selection of a flexible unstabilized auxiliary ring oscillator clock. Any of the sources may be routed out via gpo_sel=7. Additional Reg18h Table 34 clock controls allow the aux clock to be delayed by a variable amount (auxclk_modesel Reg18h<3:2>), or to be divided down by even values from 2 to 14 (auxclk_divsel Reg18h<6:4>). For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 12 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 Δ∑ Modulator Outputs (gpo_sel=10) Setting register gpo_sel=10 (Reg1B<3:0> Table 37) assigns the three lsb’s of the delta sigma modulator output to GPO<3:1> , where GPO1 is the lsb. This feature allows the possibility of using the HMC701LP6CE as a general purpose digital delta sigma modulator for many possible applications. External VCO The HMC701LP6CE is targeted for ultra low phase noise applications with an external VCO. The synthesizer has been designed to work with VCOs that can be tuned nominally over 0.5 to 4.5 Volts on the varactor tuning port with a +5V charge pump supply voltage. Slightly wider ranges are possible with a +5.5V charge pump supply or with slightly degraded performance. An external opamp active filter is required to support VCOs with tuning voltages above 5V. External VCO with Active Inverting OpAmp Loop Filter An external opamp active filter is required to support external VCOs with tuning voltages above 5V. If an inverting opamp is used with a positive slope VCO, phase_sel Reg05h <0> = 1 Table 16 must be set to invert the PFD phase polarity and obtain correct closed loop operation. Temperature Sensor The HMC701LP6CE features a built in temperature sensor which may be used as a general purpose temperature sensor. The temperature sensor is enabled via tsens_spi_enable (Reg1Eh=1 Table 40) and when enabled draws 2 mA. The temperature sensor features a built in 3-bit quantizer that allows the temperature to be read in register tsens_ temperature (Reg21h Table 43). The temperature sensor data converter is not clocked. Updates to the temperature sensor register are made by strobbing register tsens_spi_strobe (Reg00h<3> Table 11). The 3-bit quantizer operates over a -40°C to +100°C range as follows: TEMPERATURE SENSOR QUANTIZER OUTPUT Tn = floor {(Temperature +40) / 17.5 where Tn is the decimal value of register tsens_temperature} (EQ 7) 7 6 5 4 3 2 1 0 -40 -20 0 20 40 60 TEMPERATURE (°C) 80 100 Figure 9. Typical Temperature Sensor Quantizer output Temperature sensor slope is 17.5 mV/lsb. Absolute tolerances on the temperature sensor thresholds may vary by up to ±10°C worst case. Nominal temperature is given by: (EQ 8) 0 - 13 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL The Phase Frequency Detector or PFD has two inputs, one from the reference path divider and one from the VCO path divider. The PFD compares the phase of the VCO path signal with that of the reference path signal and controls the charge pump output current as a linear function of the phase difference between the two signals. The output current varies linearly over a full ±2π radians input phase difference. PFD Functions phase_sel (Reg05h<0> Table 16) inverts the phase detector, polarity for use with an inverting opamp or negative slope VCO. upout_en in Reg05h<1> Table 16 allows masking of the PFD up output, which effectively prevents the charge pump from pumping up. dnout_en in Reg05h<2> Table 16 allows masking of the PFD down output, which effectively prevents the charge pump from pumping down. Charge Pump Tri-State De-asserting both upout_en and dnout_en effectively tri-states the charge pump while leaving all other functions operating internally. PFD Jitter & Lock Detect Background In normal phase locked operation the divided VCO signal arrives at the phase detector in phase with the divided crystal signal, known as the reference signal. Despite the fact that the device is in lock, the phase of the VCO signal and the reference signal vary in time due to the phase noise of the crystal and VCO oscillators, the loop bandwidth used and the presence of fractional modulation or not. The total integrated noise on the VCO path normally dominates the variations in the two arrival times at the phase detector if fractional modulation is turned off. 0 PLL - Fractional-N - SMT Charge Pump & Phase Frequency Detector (PFD) If we wish to detect if the VCO is in lock or not we need to distinguish between normal phase jitter when in lock and phase jitter when not in lock. First, we need to understand what is the jitter of the synthesizer, measured at the phase detector in integer or fractional modes. The standard deviation of the arrival time of the VCO signal, or the jitter, in integer mode may be estimated with a simple approximation if we assume that the locked VCO has a constant phase noise, Ф2 (ƒ0), at offsets less than the loop 3 dB bandwidth and a 20 dB per decade roll off at greater offsets. The simple locked VCO phase noise approximation is shown on the left of Figure 10. Figure 10. Synthesizer Phase Noise & Jitter For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 14 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 With this simplification the single sideband integrated VCO phase noise, Ф2 , in rads2 at the phase detector is given by PLL - Fractional-N - SMT (EQ 9) where Ф2 SSB(ƒ0) is the single sideband phase noise in rads2/Hz inside the loop bandwidth, B is the 3 dB corner frequency of the closed loop PLL and N is the division ratio of the prescaler The rms phase jitter of the VCO in rads, Ф , results from the power sum of the two sidebands: 2 Ф = √ 2Ф SSB (EQ 10) Since the simple integral of (EQ 9) is just a product of constants, we can easily do the integral in the log domain. For example if the VCO phase noise inside the loop is -100 dBc/Hz at 10 kHz offset and the loop bandwidth is 100 kHz, and the division ratio N=100, then the integrated single sideband phase noise at the phase detector in dB is given by Ф2dB = 10log (Ф2(ƒ0)Bπ ⁄ N2) = -100 + 50 + 5 - 40 = -85 dBrads, or equivalently Ф = 10 -82/20 = 56 urads rms or 3.2 milli-degrees rms. While the phase noise reduces by a factor of 20logN after division to the reference, the jitter is a constant. The rms jitter from the phase noise is then given by Tjnp = Tref Ф / 2π In this example if the reference was 50 MHz, Tref = 20 nsec, and hence Tjpn = 178 femto-sec. A normal 3 sigma peak-to-peak variation in the arrival time therefore would be If the synthesizer was in fractional mode, the fractional modulation of the VCO divider will dominate the jitter. The exact standard deviation of the divided VCO signal will vary based upon the modulator chosen, however a typical modulator will vary by about ±3 VCO periods, ±4 VCO periods, worst case. If, for example, a nominal VCO at 5 GHz is divided by 100 to equal the reference at 50 MHz, then the worst case division ratios will vary by 100±4. Hence the peak variation in the arrival times caused by Δ∑ modulation of the fractional synthesizer at the reference will be (EQ 11) In this example, TjΔ∑pk = ±200 ps(104-96)/2 = ±800 psec. If we note that the distribution of the delta sigma modulation is approximately gaussian, we could approximate TjΔ∑pk as a 3 sigma jitter, and hence we could estimate the rms jitter of the Δ∑ modulator as about 1/3 of TjΔ∑pk or about 266 psec in this example. Hence the total rms jitter Tj, expected from the delta sigma modulation plus the phase noise of the VCO would be given by the rms sum , where (EQ 12) In this example the jitter contribution of the phase noise calculated previously would add only 0.764psec more jitter at the reference, hence we see that the jitter at the phase detector is dominated by the fractional modulation. In summary, we have to expect about ±0.8 nsec of normal variation in the phase detector arrival times when in fractional mode. In addition, lower VCO frequencies with high reference frequencies will have much larger variations., for example, a 1 GHz VCO operating at near the minimum nominal divider ratio of 36, would, according to (EQ 11), exhibit about ±4 nsec of peak variation at the phase detector, under normal operation. The lock detect circuit must not confuse this modulation as being out of lock. 0 - 15 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL lkd_en (Reg01h<11> Table 12) enables the lock detect functions of the HMC701LP6CE. The Lock Detect circuit in the HMC701LP6CE places a one shot window around the reference. The one shot window may be generated by either an analog one shot circuit or a digital one shot based upon an internal ring oscillator timer. Clearing lkd_ringosc_mono_select (Reg1Ah<14> Table 36) will result in a nominal ±10nsec ‘analog’ window of fixed length, as shown in Figure 11. Setting lkd_ringosc_mono_select will result in a variable length ’digital’ widow. The digital one shot window is controlled by lkd_ringosc_cfg (Reg1Ah<16:15>). The resulting lock detect window period is then generated by the number of ring oscillator periods defined in lkd_monost_duration Reg1Ah<18:17> (Table 36). The lock detect ring oscillator may be observed on the GPO2 port by setting ringosc_testmode (Reg1Ah<19> Table 36) and configuring the gpo_sel<3:0> = 0111 in (Reg1Bh Table 37). Lock detect does not function when this test mode is enabled. lkd_wincnt_max (Reg1Ah<9:0> Table 36) defines the number of consecutive counts of the VCO that must land inside the lock detect window to declare lock. If for example we set lkd_wincnt_max = 1000 , then the VCO arrival would have to occur inside the selected lock widow 1000 times in a row to be declared locked. When locked the Lock Detect flag ro_lock_detect (Reg1Fh<0> Table 41) will be set. A single occurrence outside of the window will result in clearing the Lock Detect flag, ro_lock_detect. The Lock Detect flag ro_lock_detect (Reg1Fh<0> Table 41) is a read only register, readable from the serial port. The Lock Detect flag is also output to the LD_SDO pin according to lkd_to_sdo_always (Reg1Ah<13>) and lkd_to_sdo_ automux_en (Reg1Ah<12>), both in Table 36. Setting lkd_to_sdo_always will always display the Lock Detect flag on LD_DSO. Clearing lkd_to_sdo_always and setting lkd_to_sdo_automux_en will display the Lock Detect flag on LD_SDO except when a serial port read is requested, in which case the pin reverts temporarily to the Serial Data Out pin, and returns to the lock detect function after the read is completed. 0 PLL - Fractional-N - SMT PFD Lock Detect Figure 11. Normal Lock Detect Window Lock Detect with Phase Offset When operating in fractional mode the linearity of the charge pump and phase detector are more critical than in integer mode. The phase detector linearity is worse when operated with zero phase offset. Hence in fractional mode it is necessary to offset the phase of the reference and the VCO at the phase detector. In such a case, for example with an offset delay, as shown in Figure 12, the mean phase of the VCO will always occur after the reference. The lock detect circuit window can be made more selective with a fixed offset delay by setting win_asym_enable and win_asym_up_select (Reg1Ah<11> Table 36). Similarly the offset can be in advance of the reference by clearing win_asym_up_select while leaving win_asym_enable Reg1Ah<10> set both in Table 36. For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 16 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 Figure 12. Delayed Lock Detect Window For most applications the analog one shot window is sufficient. To determine the required Lock Detect one shot window size: Required LD One Shot Window = (CP Phase Offset (ns) + 4xTvco) x 1.3 Cycle Slip Prevention (CSP) When changing frequencies the VCO is not yet locked to the reference and the phase difference at the PFD varies rapidly over a range much greater than ±2π radians. Since the gain of the PFD varies linearly with phase up to ±2π, the gain of conventional PFDs will cycle from high gain, when the phase difference approaches a multiple of 2π, to low gain, when the phase difference is slightly larger than a multiple of 0 radians. This phenomena is known as cycle slipping. Cycle slipping causes the pull-in rate during the locking phase to vary cyclically as shown in the red curve in Figure 13. Cycle slipping increases the time to lock to a value far greater than that predicted by normal small signal Laplace analysis. The HMC701LP6CE PFD features Cycle Slip Prevention (CSP), an ability to virtually eliminate cycle slipping during acquisition. When enabled, the CSP feature essentially holds the PFD gain at maximum until such time as the frequency difference is near zero. CSP allows significantly faster lock times as shown in Figure 13. The use of the CSP feature is enabled with pfds_rstb (Reg01<15> Table 12). The CSP feature may be optimized for a given set of PLL dynamics by adjusting the PFD sensitivity to cycle slipping. This is achieved by adjusting pfds_sat_deltaN (Reg1C<3:0> Table 38). CSP will cause the VCO N divider to momentarily divide by a higher or lower N value in order to pull the divided VCO phase back towards the reference edge. The maximum recommended VCO N divider deviation is no more than 20% of the target N value. For example, if N=50 for the target frequency, then the CSP Magnitude should be 10 or less so Register 1Ch Bits [3:0] would be programmed to Ah. In situations where the target N value is low, for example 36 the CSP behavior will be compromised because the minimum VCO divide value is 32 Figure 13. Cycle Slip Prevention (CSP) 0 - 17 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL A simplified diagram of the charge pump is shown in Figure 14. Charge pump up and down gains are set by cp_ UPcurrent_sel and cp_DNcurrent_sel respectively (Reg07 Table 18). Normally the registers are set to the same value. Each of the UP and DN charge pumps consist of 5-bit charge pumps with lsb of 125 µA. The current gain of the pump, in Amps/radian, is equal to the gain setting of this register divided by 2π. For example if both cp_UPcurrent_sel and cp_DNcurrent_sel are set to ’01000’ the output current of each pump will be 1mA and the gain Kp = 1mA/2π radians, or 159 uA/rad. Charge Pump Gain Trim In most applications Gain Trim is not used. However it is available for special applications. Each of the UP and DN pumps may be trimmed separately to more precise values to improve current source matching of the UP and DN values, or to allow finer control of pump gain. The pump trim controls are 3-bits, binary weighted for UP and DN, in cp_UPtrim_sel and cp_DNtrim_sel respectively (Reg 08h Table 19). LSB weight is 14.7 uA, x000 = 0 trim, x001 = 14.7 ua added trim, x111 = 100uA. Charge Pump Phase Offset Either of the UP or DN charge pumps may have a DC leakage or “offset” added. The leakage forces the phase detector to operate with a phase offset between the reference and the divided VCO inputs. It is recommended to operate with a phase offset when using fractional mode to reduce non-linear effects from the UP and DN pump mismatch. Phase noise in fractional mode is strongly affected by charge pump offset. DC leakage or “offset” may be added to the UP or DN pumps using cp_UPoffset_sel and cp_DNoffset_sel (Reg08 Table 19). These are 4 bit registers with 28.7uA LSB. Maximum offset is 430uA. PLL - Fractional-N - SMT 0 Charge Pump Gain As an example, if the main pump gain was set at 1mA, an offset of 373uA would represent a phase offset of about (392/1000)*360 = 133 degrees. For best spectral performance in Fractional Mode the leakage current should be programmed to: Required Leakage Current (µA) = (2.5E-9 + 4xTvco) x Fcomparison (Hz) x CP current (µA) Figure 14. Charge Pump Gain, Trim and Phase Offset Control For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 18 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 Frequency Programming The HMC701LP6CE can operate in either fractional mode or integer mode. In integer mode of operation the delta sigma modulator is disabled. Frequency programming and mode control is described below. Fractional Frequency The fractional frequency synthesizer, when operating in fractional mode, can lock to frequencies which are fractional multiples of the reference frequency. Fractional mode is the default mode. To run in fractional mode ensure that dsm_integer_mode Reg12h<5> Table 29 is clear and dsm_rstb Reg01<13> Table 12). Then program the frequency as explained below: The output frequency of the synthesizer is given by, fvco, where Fractional Frequency of VCO (EQ 13) where Nint is the integer division ratio, an integer number between 36 and 65,533 (dsm_intg (Reg0Fh Table 26)) Nfrac is the fractional part, a number from 1 to 224 (dsm_frac Reg10h Table 27) R is the reference path division ratio, (rfp_div_ratio Reg03h<13:0> Table 14) fxtal is the frequency of the crystal oscillator input (XSIN or XREF Figure 4) fxtal R fref Nint Nfrac = 50 MHz =1 = 50 MHz = 46 =1 As an Example: (EQ 14) In this example the output frequency of 2,300,000,002.98 Hz is achieved by programming the 16-bit binary value of 46d = 2Eh = 0000 0000 0010 1110 into dsm_intg. Similarly the 24-bit binary value of the fractional word is written into dsm_frac, 1d = 000 001h = 0000 0000 0000 0000 0000 0001 0 - 19 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Example 2: Set the output to 4.600 025 GHz using a 100 MHz reference, R=2. (EQ 15) Since Nfrac must be an integer number, the actual fractional frequency will be 25,001.17 Hz, an error of 1.17 Hz. Here we program the 16-bit Nint = 92d = 5Ch = 0000 0000 0101 1100 and the 24-bit Nfrac = 8389d = 20C5h = 0000 0010 0000 1100 0101 In addition to the above frequency programming words, the fractional mode must be enabled using the frac register. Other DSM configuration registers should be set to the recommended values. Register setup files are available on request. Integer Frequency The synthesizer is capable of operating in integer mode. In integer mode the digital Δ∑ modulator is normally shut off and the division ratio of the VCO divider is set at a fixed value. To run in integer mode set dsm_integer_mode (Reg12h<3> Table 29) and clear dsm_rstb (Reg01h<13> Table 12). Then program the integer portion of the frequency, NINT, as explained by (EQ 13), ignoring the fractional part. PLL - Fractional-N - SMT Find the nearest integer value, Nint, Nint = 92, fint = 4.600 000 GHz This leaves the fractional part to be ffrac =25 kHz Frequency Hopping Trigger If the synthesizer is in fractional mode, a write to the fractional frequency register, Reg10h Table 27, will initiate the frequency hop on the falling edge of the 31st clock edge of the serial port write (see Figure 18). If the integer frequency register, Reg0Fh Table 26, is written when in fractional mode the information will be buffered and only executed when the fractional frequency register is written. If the synthesizer is in integer mode, a write to the integer frequency register, Reg0Fh Table 26, will initiate the frequency hop on the falling edge of the 31st clock edge of the serial port write (see Figure 18). Power On Reset (POR) Normally all logic cells in the HMC701LP6CE are reset when the device digital power supply, DVDD, is applied. This is referred to as Power On Reset, or just POR. POR normally takes about 500us after the DVDD supply exceeds 1.5V, guaranteed to be reset in 1msec. Once the DVDD supply exceeds 1.5V, the POR will not reset the digital again unless the supply drops below 100mV. Soft Reset The SPI registers may also be soft reset by an SPI write to strobe global_swrst_regs (Reg00h<0> Table 11). All other digital, including the fractional modulator, may be reset with an SPI write to strobe global_swrst_dig (Reg00h<1> Table 11). Hardware Reset The SPI registers may also be hardware reset by holding RSTB, pin 19, low. For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 20 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 Power Down The HMC701LP6CE may be powered down by writing a zero to Reg01h Table 12. In power down state the HMC701LP6CE should draw less than 10uA. It should be noted that Reg01h is the Enable and Reset Register which controls 16 separate functions in the chip. Depending upon the desired mode of operation of the chip, not all of the functions may be enabled when in operation. Hence power up of the chip requires a selective write to Reg01 bits. An easy way to return the chip to its prior state after a power down is to first read Reg01h and save the state, then write a zero to Reg01h for reset and then simply rewrite the previous value to restore the chip to the desired operating mode. CW Sweeper Mode The HMC701LP6CE features a built in frequency sweeper function. This function supports external or automatic triggered sweeps. The maximum sweep range is limited to 255 x Fxtal/R. For example, with a 25 MHz comparison frequency, the maximum sweep range is 6375 MHz. The start and end frequency points must be within 6375 MHz of one another. For sweep operation the Delta-Sigma Modulator mode should be Feed Forward (Register 12h Bits [9:8] = 11) otherwise discontinuities may occur when crossing integer-N boundaries (harmonic multiples of the comparison frequency). Sweeper Modes include: a. 2-Way Sweep Mode: alternating positive and negative frequency ramps. b. 1-Way Sweep Mode c. Single Step Ramp Mode Applications include test instrumentation, FMCW sensors, automotive radars and others. The parameters of the sweep function are illustrated in Figure 15. The sweep generator is enabled with ramp_enable in (Reg14h<1> Table 30). The sweep function cycles through a series of discrete frequency values, which may be a. Stepped by an automatic sequencer, or b. Single stepped by individual triggers in Single Step Mode. Triggering of each sweep, or step, may be configured to operate: a. Via a serial port write to Reg14h<2> ramp_trigg (if Reg 14h<2> = 0 ) b. Automatically generated internally, c. Triggered via TTL input on GPO3 Reg14h<5> = 1. Sweep parameters are set as follows: Initial Frequency, fo = Current frequency value of the synthesizer, (EQ 15) Final Frequency, ff = Frequency of the synthesizer at the end of the ramp The frequency step size while ramping is controlled by rampstep, (Reg15h Table 31). 24 Frequency Step Size ∆ƒstep = rampstep • fxtal / 2 where R is the value of the reference divider (rfp_div_ratio in Table 14) • R Clearing or setting ramp_startdir_dn, (Reg14h<4> Table 30), sets the initial ramp direction to be increasing or decreasing in frequency respectively. Setting ramp_singledir (Reg14h<7> Table 30), restricts the direction of the sweep to the initial sweep direction only. The sweeper timebase Tref is the period of the divided reference, fPFD, at the phase detector Tref The total number of ramp steps taken in a single sweep is given by ramp_steps_number in Reg16h Table 32. The total time to ramp from fo to ff is given by Tramp = Tref 0 - 21 • ramp_steps_number For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 CW Sweeper Mode (Continued) • ramp_steps_number Sweeper action at the end of sweep depends upon the mode of the sweep: a. With both ramp_singledir and ramp_repeat_en disabled, at the end of the ramp time, Tramp, the sweeper will dwell at the final frequency ff, until a new trigger is received. The next trigger will reverse the current sequence, starting from ff, and stepping back to fo. Odd triggers will ramp in the same direction as the initial ramp, even triggers will ramp in the opposite direction. b. with ramp_singledir enabled and ramp_repeat_en disabled, at the end of the ramp time, Tramp, the sweeper will dwell at the final frequency ff, until a new trigger is received. The second trigger will hop the synthesizer back to the initial frequency, fo. The third trigger will restart the sweep from fo. Hence all odd numbered triggers will start a new ramp in the same direction as the initial ramp, even numbered triggers will hop the synthesizer from the current frequency to fo , where it will wait for a trigger to start a sweep. Ramp Busy In all types of sweeps ramp_busy will indicate an active sweep and will stay high between the 1st and nth ramp step. ramp_busy may be monitored one of two ways. ramp_busy is readable via read only register Reg1Fh<5> Table 41. ramp_busy may also be monitored on GPO2, hardware pin 24, by setting Reg1Bh<3:0> =8h Table 37. Autosweep Mode The Autosweep mode is similar to Figure 15 except that once started, triggers are not required. Once enabled, (ramp_ repeat_en=1 Reg14h<3> Table 30) the Autosweep mode initiates the first trigger, steps n times, one step per ref clock cycle, and then waits for the programmed dwell period and automatically triggers the ramp in the opposite direction. The sweep process continues alternating sweep directions until disabled. dwell_time (Reg17h Table 33) controls the number of Tref periods to wait at the end of the ramp before automatically retriggering a new sweep. PLL - Fractional-N - SMT The final ramp frequency, ff, is given by ƒƒ = ƒi + ∆ƒstep 2-Way Sweeps If ramp_repeat_en (Reg14h<3> Table 30) is cleared, then the ramps are triggered by a. Writing to ramp_trigg (Reg14h<2> Table 30), if bit <2> = 0, or b. by rising edge TTL signal input on GPO3, if ramp_trig_ext_en is set, and GPO3 is enabled. All functions are the same in Figure 15 for Autosweep or 2-Way Triggered sweeps, the only difference is the trigger source is generated internally for autosweep, and is input via serial port or GPO3 for triggered sweeps. Sweep_busy will go high at the start of every ramp and stay high until the nth step in the ramp. For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 22 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 Figure 15. 2-Way Sweep Control via Trigger Triggered 1-Way Sweeps 1-Way sweeps are shown inFigure 16. Unlike 2-Way sweeps, 1-Way sweeps require that the VCO hop back to the start frequency after the dwell period. Triggered 1-Way sweeps also require a 3rd trigger to start the new sweep. The 3 rd trigger must be timed appropriately to allow the VCO to settle after the large frequency hop back to the start frequency. Subsequent odd numbered triggers will start the 1-Way sweep and repeat the process. Figure 16. 1-Way Sweep Control 0 - 23 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL A Single Step 1-Way Ramp is shown in Figure 17. In this mode, a trigger is required for each step of the ramp. Single step will function in either 1-Way or 2-Way ramps. Similar to autosweep, the ramp_busy flag will go high on the first trigger, and will stay high until the nth trigger. The n+1 trigger will cause the ramp to jump to the start frequency in 1-way ramp mode. The n+2 trigger will restart the 1-way ramp. PLL - Fractional-N - SMT 0 Single Step Ramp Mode Figure 17. Single Step Ramp Mode The user should be aware that the synthesized ramp is subject to normal phase locked loop dynamics. If the loop bandwidth in use is much wider than the rate of the steps then the locking will be very fast and the ramp will have a staircase shape. If the update rate is higher than the loop bandwidth, as is normally the case, then the loop will not fully settle before a new frequency step is received. Hence the swept output will have a small lag and will sweep in a near continuous fashion. For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 24 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL PLL - Fractional-N - SMT 0 MAIN SERIAL PORT The HMC701LP6CE features a four wire serial port for simple communication with the host controller. Register types may be Read Only, Write Only, Read/Write or Strobe, as described in the registers descriptions. The synthesizer also features an auxiliary 3-wire serial port, known as the VCO Serial Port. The VCO Serial Port is a write only interface from the synthesizer to an optional switched resonator VCO that supports 3-wire serial port control. Typical main serial port operation can be run with SCLK at speeds up to 50 MHz. Serial port registers are described in the section REGISTER MAP. Serial Port WRITE Operation AVDD = DVDD = 3V ±10%, AGND = DGND = 0V Table 4. Timing Characteristics Parameter Conditions Min. Typ. Max Units t1 SEN to SCLK setup time 8 nsec t2 SDI to SCLK setup time 10 nsec t3 SDI to CLK hold time 10 nsec t4 SCLK high duration 8 nsec t5 SCLK low duration 8 nsec t6 SEN High duration 640 nsec t7 SEN low duration 20 nsec A typical WRITE cycle is shown in Figure 18. a. The Master (host) both asserts SEN (Serial Port Enable) and clears SDI to indicate a WRITE cycle, followed by a rising edge of SCLK. b. The slave (synthesizer) reads SDI on the 1st rising edge of SCLK after SEN. SDI low initiates the WRITE cycle (/WR) c. Host places the six address bits on the next six falling edges of SCLK, MSB first. d. Slave registers the address bits in the next six rising edges of SCLK (2-7). e. Host places the 24 data bits on the next 24 falling edges of SCK, MSB first . f. Slave registers the data bits on the next 24 rising edges of SCK (8-31). g. SEN is de-asserted on the 32nd falling edge of SCLK. h. The 32nd rising edge of SCLK completes the cycle Figure 18. Serial Port Timing Diagram - WRITE 0 - 25 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL The synthesizer uses the multi-purpose pin, LD_SDO, for both Lock Detect and Serial Data Out (SDO) functions. The registers lkd_to_sdo_automux_en (Reg1A<12>) and lkd_to_sdo_always (Reg1A<13> Table 36) determine how the Data Output pin is muxed with the Lock Detect function. If both of the registers are cleared, then the pin is exclusively SDO. If automux is enabled, the pin switches to SDO when the RD function is sensed on the 1st rising edge of SCLK. If lkd_to_sdo_always is set, then the pin LD_SDO is dedicated for Lock Detect only, and it is not possible to read from the synthesizer. A typical READ cycle is shown in Figure 19. a. The Master (host) asserts both SEN (Serial Port Enable) and SDI to indicate a READ cycle, followed by a rising edge SCLK b. The slave (synthesizer) reads SDI on the 1st rising edge of SCLK after SEN. SDI high initiates the READ cycle (RD) c. Host places the six address bits on the next six falling edges of SCLK, MSB first. d. Slave registers the address bits on the next six rising edges of SCLK (2-7). e. Slave places the 24 data bits on the next 24 rising edges of SCK (8-31), MSB first . f. Host registers the data bits on the next 24 falling edges of SCK (8-31). g. SEN is de-asserted on the 32nd falling edge of SCLK. h. The 32nd falling edge of SCLK completes the cycle 0 PLL - Fractional-N - SMT Main Serial Port READ Operation Figure 19. Serial Port Timing Diagram - READ For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 26 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 REGISTER MAP PLL - Fractional-N - SMT Reg 00h Chip ID (Read Only) Register 0 - 27 Bit Type [23:0] Ro Name Chip ID Width Default 24 581502 Description Chip ID Table 11. Reg 00h Strobe (Write Only) Register Bit Type 0 STR Name global_swrst_regs Width Default 1 0 Description Strobe to soft reset the SPI registers 1 STR global_swrst_dig 1 0 Strobe to soft reset the rest of digital 2 STR mcnt_resynch 1 0 Reserved 3 STR tsens_spi_strobe 1 0 Strobe to clock the temp measurement on demand Table 12. Reg 01h Enable & Reset Register Bit Type 0 R/W malg_vcobug_en Name 1 Default 1 VCO Buffer Enable Description 1 R/W mag_bias_en 1 1 Bias enable 2 R/W rfp_div_en 1 0 Enables / Holds refdiv in reset Holding Ref divider in reset is equivalent to bypassing the divider, see Figure 4 3 R/W xrefmux_todig_en 1 1 Enables clock gate for xtal muxed (sq or sin) reference to digital 4 R/W rfp_div_todig_en 1 0 Enables divided reference clock to the digital see Figure 4 5 R/W rfp_sqr_todig_en 1 0 Enables square wave xtal clock to main digital see Figure 4 6 R/W rfp_sin_todig_en 1 0 Enables sine wave xtal clock to main digital see Figure 4 7 R/W rfp_bug_sq_en 1 1 Enables Square wave Ref Buffer, see Figure 4 8 R/W rfp_bug_sin_en 1 0 Enables Sine wave Ref Buffer, see Figure 4 9 R/W vcop_todig_en 1 0 1= divided VCO as digital, Δ∑ modulator clock 0= Divided Ref path as the 10 R/W vcop_presc_en 1 1 Enables the prescaler bias 11 R/W pfd_lkd_en 1 0 Enable / Resetb to digital lockdetect circuit and PFD’s lockdetect output gates 12 R/W cp_en 1 1 Charge Pump Enable, disable is tri-stated output 13 R/W dsm_rstb 1 0 1 - Enables fractional modulator see also dsm_integer_mode Reg12h<3> 14 R/W lkd_rstb 1 0 1 - enables lock detect circuit 15 R/W pfds_rstb 1 1 CSP PFD FF rstb 1 - Enables the Cycle Slip Prevention (CSP) feature of the PFD For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 13. Reg 02h Serial Data Out Force Register Type Name Default Description 0 R/W malg_sdo_driver_force_val 1 Serial Data Out Force value This value may be forced onto LD_SDO by setting malg_sdo_driver_force_en 1 R/W malg_sdo_driver_force_en 1 Serial Data Out EN Force enable Places value from malg_sdo_driver_force_val on SDO Table 14. Reg 03h Reference Path Register Bit Type Name Default Description 13:0 R/W rfp_div_ratio also referred to as ‘R’ 0 Divides the crystal input by this number ‘R’ if rfp_div_en=1 and rfp_div_select = 1 rfp_div_ratio = 0 not allowed 2<=div_ratio<=2^14 see Figure 4 14 R/W rfp_div_select 0 1 = reference divider enabled 0 = bypass ref divider see Figure 4 15 R/W rfp_auto_refdiv_sel_en 0 1 = auto ref divider enable or bypass is automatic if rfp_div_ratio = 1, bypass divider if rfp_div_bypass ~=1 use divider see Figure 4 16 R/W rfp_buf_sin_sel 0 Selects sine wave reference for normal operation see Figure 4 PLL - Fractional-N - SMT Bit Table 15. Reg 04h Prescaler Duty Cycle Register Bit 0 Type R/W Name vcop_dutycycmode Default 0 Description Extends the low time from 15 to 47 VCO cycles for large divide ratios Table 16. Reg 05h Phase Freq Detector Register (pfd) Bit Type Name Default Description 0 R/W pfd_phase_sel 0 Inverts PFD Polarity 0 = Passive Filter +ve slope VCO 1 = Passive Filter -ve slope VCO 1 = Active inverting filter, +ve slope VCO 0 = Active inverting filter, -ve slope VCO 1 R/W pfd_upout_en 1 Allows masking of the up outputs between PFD and CP 2 R/W pfd_dnout_en 1 Allows masking of the dn outputs between PFD and CP Table 17. Reg 06h Phase Freq Detector Delay Register Bit Type 2:0 R/W Name pfd_del_sel Default 2 Description Delay line setpoint to PFD For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 28 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 18. Reg 07h Charge Pump UP/DN Control Register PLL - Fractional-N - SMT Bit Type Name Default Description 4:0 R/W cp_UPcurrent_sel 16 Sets Charge-Pump Up gain, 125uA lsb, binary, 4mA max 9:5 R/W cp_DNcurrent_sel 16 Sets Charge-Pump Dn gain, 125uA lsb, binary, 4mA max Table 19. Reg 08h Charge Pump Trim & Offset Register Bit Type 3:0 R/W cp_UPtrim_sel Name Default 0 Trim Up gain, 14.3uA lsb, binary, 100uA max Description 7:4 R/W cp_DNtrim_sel 0 Trim Dn gain, 14.3uA lsb, binary, 100uA max 11:8 R/W cp_UPoffset_sel 4 Up Offset leakage current, 28.7uA lsb, binary, 430uA max 15:12 R/W cp_DNoffset_sel 0 Dn Offset leakage current, 28.7uA , binary, 430uAmax 17:16 R/W cp_amp_bias_sel 2 Charge Pump Dummy Branch Op amp bias selection, 100uA Table 20. Reg 09h Charge Pump EN Register Bit Type 0 R/W cp_pull_updn_en Name Default 0 Enables CP UP/Down Control Reg09 [1] Description 1 R/W cp_pull_dn_upb 0 0 - Forces Charge Pump Up when Reg09[0]=1 1 - Forces Charge Pump DN when Reg09[0]=1 Table 21. Reg 0Ah Reserved Bit Type 23:0 R/W Name Reserved Default 0 Description Reserved Table 22. Reg 0Bh Reserved Bit Type 23:0 R/W Name Reserved Default 0 Description Reserved Table 23. Reg 0Ch Reserved Bit Type 23:0 R/W Name Reserved Default 0 Description Reserved Table 24. Reg 0Dh Reserved Bit Type 23:0 R/W Name Reserved Default 0 Description Reserved Table 25. Reg 0Eh Reserved 0 - 29 Bit Type 23:0 R/W Name Reserved Default 0 Description Reserved For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL Bit 15:0 Type R/W Name dsm_intg Default 200d Description unsigned integer portion of VCO divider value, also known as NINT, see (EQ 12) Table 27. Reg 10h Fractional Division Register Bit 23:0 Type R/W Name dsm_frac Default 0 Description unsigned fractional portion of VCO divider also known as NFRAC, see (EQ 12) Table 28. Reg 11h Seed Register Bit 23:0 Type R/W Name dsm_seed Default 0 Description unsigned seed value for Δ∑ modulator sets the start phase of the modulator Table 29. Reg 12h Delta Sigma Modulator Register Bit Type 0 R/W dsm_ref_clk_select Name Default 0 use reference instead of divider Description 1 R/W dsm_invert_clk_sd3 1 invert Δ∑ clk 2 R/W dsm_invert_clk_rph 0 inverts the ref clock phase 1- enables Integer Mode, bypasses the Δ∑ modulator, leaves it running see also dsm_rstb Reg01h<13> to disable the modulator 3 R/W dsm_integer_mode 0 4 R/W Reserved 0 5 R/W Reserved 0 6 R/W dsm_xref_sin_select 0 when xref is selected specifies that the sine source is used 7 R/W dsm_autoseed 1 automatic seed load when changing the frac part, uses value in seed 9:8 R/W dsm_order 2 00-first order 01-second 10-third fb 11-third ff 13:10 R/W dsm_quant_max 4’b0111 max value allowed out of Δ∑ modulator quantizer limits are +7 to -8, typ ±3 or ±4 17:14 R/W dsm_quant_min 4’b1000 min value allowed out of Δ∑ modulator quantizer limits are +7 to -8, typ ±3 or ±4 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] PLL - Fractional-N - SMT 0 Table 26. Reg 0Fh Integer Division Register 0 - 30 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 30. Reg 14h CW Sweep Control Register PLL - Fractional-N - SMT The maximum sweep range is limited to 255 x Fxtal/R. Delta-Sigma Modulator mode should be Feed Forward when using Sweep feature (Register 12h Bits [9:8] = 11. Bit Type 0 R/W clear_ovf_undf Name Default 0 asynchronous clear for ovf/undf flags Description 1 R/W ramp_enable 0 Ramp En/rstb 1= enables the CW Ramp Function 2 R/W ramp_trigg 0 Write always triggers ramps if bit <2> = 0, if bit <2> = 1, Ramp will not trigger, bit <2> must be reset to 0 first 3 R/W ramp_repeat_en 0 Ramp Repeat Seq enable 1= enables autotrigger of ramps 0 = ramp_trigg starts each ramp 4 R/W ramp_startdir_dn 0 Ramp start direction 1= Start with Ramp Down 0= Start with Ramp Up 5 R/W ramp_trig_ext_en 0 Enable hardware trigger on GPO3 pin 6 R/W ramp_singlestep 0 Ramp single step, advances the ramp to the next step, and holds frequency 7 R/W ramp_singledir 0 Ramps in one direction only with hop to start at end of ramp Table 31. Reg 15h CW Sweep Ramp Step Register The maximum sweep range is limited to 255 x Fxtal/R. Delta-Sigma Modulator mode should be Feed Forward when using Sweep feature (Register 12h Bits [9:8] = 11. Bit Type 23:0 R/W Name ramp_step Default 2048 Description Ramp Step size Table 32. Reg 16h CW Sweep Ramp Step Number Register The maximum sweep range is limited to 255 x Fxtal/R. Delta-Sigma Modulator mode should be Feed Forward when using Sweep feature (Register 12h Bits [9:8] = 11. Bit Type 23:0 R/W Name ramp_steps_number Default 2048 Description Ramp Number of steps in ramp Table 33. Reg 17h CW Sweep Dwell Time Register Bit 23:0 Type R/W Name ramp_dwell_time Default 2048 Description Ramp Number of cycles to hold at top/bottom in repeat mode [1] Phase-Error Measurement and Compensation in PLL Frequency Synthesizers for FMCW, Sensors—I: Context and Application, Pichler, Stelzer, Member, IEEE, Seisenberger, and Vossiek, IEEE Transactions on Circuits and Systems—I, VOL. 54, No. 5, May 2007 0 - 31 For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 34. Reg 18h Auxiliary Oscillator Register 1 Type Name Default Description 1:0 R/W dsmclk_auxclk_insel 0 Selects the input clk for auxclk 0:vcodiv 1:xrefsq or sin 2:refdiv 3:ring oscillator from mono, est 300 MHz to 1 GHz 3:2 R/W dsmclk_auxclk_modesel 0 0: bypass-no delay 1: pass through w/ delay 2: ring-out constant 3: ring-out seeded/gated divider selection auxclk value divby 000 001 010 011 100 101 110 111 1 2 4 6 8 10 12 14 6:4 R/W dsmclk_auxclk_divsel 2 7 R/W dsmclk_auxclk_sel 0 selects auxclk (if=1) as natural reference clk input of sigma delta 8 R/W dsmclk_auxmod_lfsr_en 0 enables 10-bit lfsr inside the delay modulator (clocked by auxclk or auxclkb) 9 R/W dsmclk_auxmod_accum_en 0 enables 8-bit accumulator inside the delay modulator (clocked by auxclk or auxclkb) 11:10 R/W dsmclk_auxmod_mode 0 delay modulation mode 0: auxmod_lodly_in passthrough 1: accumulator based square-wave 2: lfsr (lo-amp) 3: lfsr (hi-amp) 19:12 R/W dsmclk_auxmod_fracstep 3 step-size of accumulator (changes square-wave value once it wraps through 256) 22:20 R/W dsmclk_auxmod_lodly 0 value of delay-element (when auxmod_mode=0) or low value used during sq-wave modulation PLL - Fractional-N - SMT Bit Table 35. Reg 19h Auxiliary Oscillator Register 2 Bit Type Name Default Description 2:0 R/W dsmclk_auxmod_hidly 7 hi value of delay element during sq-wave modulation 3 R/W dsmclk_auxmod_clkinv 1 optionally inverts auxclk as used by the modulator 4 R/W dsmclk_auxmod_clkwring 9 select LKD ringosc to clock the LFSR For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 32 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 36. Reg 1Ah Lock Detect Register PLL - Fractional-N - SMT Bit 0 - 33 Type Name Default 10’d40 Description threshold count in the timer window to declare lock (reference cycles) 9:0 R/W lkd_wincnt_max 10 R/W lkd_win_asym_enable 0 Enables asymmetric lock detect window (nominal 10nsec) 11 R/W lkd_win_asym_up_select 0 Sets polarity of the window 12 R/W lkd_to_sdo_automux_en 0 Muxes the lkd output signal to SDO when SDO is not being used for Main Serial Port Data Outputs (Read Operation) 13 R/W lkd_to_sdo_always 0 Muxes the lkd output signal to SDO always, not possible to do Main Serial Port Read in this state 14 R/W lkd_ringosc_mono_select 0 1 select ringosc based oneshot for lock detect window 0 selects analog based oneshot 16:15 R/W lkd_ringosc_cfg 0 “00” fastest “11” slowest 18:17 R/W lkd_monost_duration 0 “00” shortest “11” longest 19 R/W lkd_ringosc_testmode 0 enables the ring osc by itself for testing For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 37. Reg 1Bh GPO Control Register Type Name gpo_sel 3:0 R/W Default 0 Description Selects data to be driven on GPO ports gpo_sel<3:0> = 0000 GPO3 <=gposel_0_data<2> GPO2 <= gposel_0_data<1> GPO1 <= gposel_0_data<0> gpo_sel<3:0> = 0001 GPO3 <= xref_clk_in GPO2 <= ref_clk_in GPO1 <= vco_div_clkin gpo_sel<3:0> = 0010 GP03 <= pfd_up_in GP02 <= pfd_dn_in GP01 <= LKD_monost_window gpo_sel<3:0> = 0011 GP03 <= pfd_sat_ref_in GP02 <= pfd_sat_vco_div_in GP01 <= delta_integer_cycslip_sel, this strobe holds the gain of the PFD at max for anti-cycle slipping gpo_sel<3:0> = 0100 GP03 <= xref_clk_in GP02 <= xref_sin_in GP01 <= sd_frac_strobe_sync, internally synchronized frac strobe gpo_sel<3:0> = 0101 Reserved gpo_sel<3:0> = 0110 GP03 <= SD_Intz1<1> GP02 <=SD_Intz1<2> GP01 <= SD_Intz1<3> 3-bit quantized version of the VCO phase gpo_sel<3:0> = 0111 GP03 <= aux_clk GP02 <= ringosc_test GP01 <= clk_SD gpo_sel<3:0> = 1000 GP03 <= 00 GP02 <= ramp_busy GP01 <= Reserved gpo_sel<3:0> = 1001 Reserved gpo_sel<3:0> = 1010 GP03 <= Δ∑ Quantizer Output 3rd lsb GP02 <= Δ∑ Quantizer Output 2nd lsb GP01 <= Δ∑ Quantizer Output lsb 6:4 R/W gpo_sel_0_data this data is driven on gpo if gpo_sel==0 7 R/W gpo_dig_drive_en enables Tri-state drivers on GPO output pads gpo_ind_drive_dis 10:8 R/W 000 = all GPO pad drivers enabled xx1 = disable GPO1 pad driver x1x = disable GPO2 pad driver 1xx = disable GPO3 pad driver For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] PLL - Fractional-N - SMT Bit 0 - 34 HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 38. Reg 1Ch Phase Detector CSP Register PLL - Fractional-N - SMT Bit Type Name Default Description 0= Cycle Slip Prevention (CSP) disabled 3:0 R/W pfds_sat_deltaN 5’d4 4 R/W pfds_rstb_force 0 5 R/W pfds_rstb 1 4-bit value to advance or retard phase detector in VCO cycles if it reaches 2pi , i.e. cycle slip prevention. 1st bit is polarity, enabled by rstb CSP PFD Flip-flops RSTB: 1 - controlled by the pfds_rstb bit: 0 - auto-controlled by the CSP logic Forces the PFD into reset, which tristates charge pump, freezes charge on the loop filter, and hence opens the loop CSP PFD FF rstb 1 - Enables the Cycle Slip Prevention (CSP) feature of the PFD Table 39. Reg 1Dh Reserved Bit Type 23:0 R/W Name Reserved Default 0 Description Reserved Table 40. Reg 1Eh Temperature Sensor Register Bit 0 Type R/W Name tsens_spi_enable Default 0 Description Enable the temperature sensor, draws ~2mA current, must strobe tsens_spi_strobe Reg 00h <3> Table 41. Reg 1Fh LD, VCO & Ramp Busy Read Only Register Bit Type Name Default Description 0 RO ro_lock_detect 0 1 = locked, 0 = unlocked 3:1 RO ro_dsm_overflow 0 1 = modulator overflow 4 RO Reserved 0 Reserved 5 RO ro_ramp_busy 0 Sweeper status flag, set when ramp is busy, cleared when at end of ramp or not used Table 42. Reg 20h Reserved Bit Type 23:0 RO Name Reserved Default 0 Description Reserved Table 43. Reg 21h Temperature Sensor Read Only Register Bit 6:0 0 - 35 Type RO Name tsens_temperature Default 0 Description Current Temperature from temp sensor lsb = 17.5°C 0000111 = Temp >= 82.5°C 0000110 = Temp 0000000 = Temp <=-22.5°C tsens_temperature = floor ((Temp+40)/17.5) For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] HMC701LP6CE v07.0411 8 GHz 16-Bit Fractional-N PLL 0 Table 44. Reg 22h Autotune Result Register Type RO Name Default Reserved 0 Description PLL - Fractional-N - SMT Bit 23:0 Reserved Outline Drawing NOTES: 1. PACKAGE BODY MATERIAL: LOW STRESS INJECTION MOLDED PLASTIC SILICA AND SILICON IMPREGNATED. 2. LEAD AND GROUND PADDLE MATERIAL: COPPER ALLOY. 3. LEAD AND GROUND PADDLE PLATING: 100% MATTE TIN. 4. DIMENSIONS ARE IN INCHES [MILLIMETERS]. 5. LEAD SPACING TOLERANCE IS NON-CUMULATIVE. 6. PAD BURR LENGTH SHALL BE 0.15mm MAX. PAD BURR HEIGHT SHALL BE 0.25mm MAX. 7. PACKAGE WARP SHALL NOT EXCEED 0.05mm 8. ALL GROUND LEADS AND GROUND PADDLE MUST BE SOLDERED TO PCB RF GROUND. 9. REFER TO HITTITE APPLICATION NOTE FOR SUGGESTED PCB LAND PATTERN. Package Information Part Number Package Body Material Lead Finish HMC701LP6CE RoHS-compliant Low Stress Injection Molded Plastic 100% matte Sn MSL Rating MSL1 [2] Package Marking [1] H701 XXXX [1] 4-Digit lot number XXXX [2] Max peak reflow temperature of 260 °C For price, delivery and to place orders: Hittite Microwave Corporation, 2 Elizabeth Drive, Chelmsford, MA 01824 978-250-3343 tel • 978-250-3373 fax • Order On-line at www.hittite.com Application Support: [email protected] 0 - 36