a OC-48/OC-48 FEC Clock and Data Recovery IC with Integrated Limiting Amp ADN2811 FEATURES Meets SONET Requirements for Jitter Transfer/ Generation/Tolerance Quantizer Sensitivity: 4 mV Typ Adjustable Slice Level: 100 mV 1.9 GHz Minimum Bandwidth Patented Clock Recovery Architecture Loss of Signal Detect Range: 3 mV to 15 mV Single Reference Clock Frequency for Both Native SONET and 15/14 (7%) Wrapper Rate Choice of 19.44 MHz, 38.88 MHz, 77.76 MHz, or 155.52 MHz REFCLK LVPECL/LVDS/LVCMOS/LVTTL Compatible Inputs (LVPECL/LVDS Only at 155.52 MHz) 19.44 MHz Oscillator On-Chip to Be Used with External Crystal Loss of Lock Indicator Loopback Mode for High Speed Test Data Output Squelch and Bypass Features Single-Supply Operation: 3.3 V Low Power: 540 mW Typical 7 mm 7 mm 48-Lead LFCSP APPLICATIONS SONET OC-48, SDH STM-16, and 15/14 FEC WDM Transponders Regenerators/Repeaters Test Equipment Backplane Applications PRODUCT DESCRIPTION The ADN2811 provides the receiver functions of quantization, signal level detect, and clock and data recovery at OC-48 and OC-48 FEC rates. All SONET jitter requirements are met, including jitter transfer, jitter generation, and jitter tolerance. All specifications are quoted for –40C to +85C ambient temperature, unless otherwise noted. The device is intended for WDM system applications and can be used with either an external reference clock or an on-chip oscillator with external crystal. Both the 2.48 Gb/s and 2.66 Gb/s digital wrapper rate is supported by the ADN2811, without any change of reference clock. This device, together with a PIN diode and a TIA preamplifier, can implement a highly integrated, low cost, low power, fiber optic receiver. The receiver front end signal detect circuit indicates when the input signal level has fallen below a user-adjustable threshold. The signal detect circuit has hysteresis to prevent chatter at the output. The ADN2811 is available in a compact 7 mm × 7 mm 48-lead chip scale package. FUNCTIONAL BLOCK DIAGRAM SLICEP/N 2 VCC VEE CF1 ADN2811 CF2 LOL LOOP FILTER 2 PIN 2 QUANTIZER NIN PHASE SHIFTER PHASE DET. LOOP FILTER VCO FREQUENCY LOCK DETECTOR /n REFSEL[0..1] REFCLKP/N XO1 XTAL OSC XO2 VREF LEVEL DETECT DATA RETIMING 2 THRADJ SDOUT FRACTIONAL DIVIDER DATAOUTP/N REFSEL 2 CLKOUTP/N RATE REV. A Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective companies. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781/329-4700 www.analog.com Fax: 781/326-8703 © 2002 Analog Devices, Inc. All rights reserved. (T = T to T , VCC = V ADN2811–SPECIFICATIONS unless otherwise noted.) A Parameter MIN MAX MIN Conditions to VMAX, VEE = 0 V, CF = 4.7 F, SLICEP = SLICEN = VCC, Min QUANTIZER–DC CHARACTERISTICS Input Voltage Range @ PIN or NIN, DC-Coupled Peak-to-Peak Differential Input Input Common-Mode Level DC-Coupled. (See Figure 22) PIN–NIN, AC-Coupled1, BER = 1 10–10 Differential Input Sensitivity Input Overdrive Figure 4 Input Offset Input rms Noise BER = 1 10–10 0 Max Unit 1.2 2.4 V V V mV p-p mV p-p µV µV rms 0.4 4 2 500 244 QUANTIZER–AC CHARACTERISTICS Upper –3 dB Bandwidth Small Signal Gain Differential S11 @ 2.5 GHz Input Resistance Differential Input Capacitance Pulsewidth Distortion2 10 5 1.9 54 –15 100 0.65 10 QUANTIZER SLICE ADJUSTMENT Gain SliceP–SliceN = 0.5 V Control Voltage Range SliceP–SliceN Control Voltage Range @ SliceP or SliceN Slice Threshold Offset 0.115 –0.8 1.3 0.200 GHz dB dB Ω pF ps 0.300 +0.8 VCC V/V V V mV 18.0 7.6 5.2 5 7.8 8.5 9.9 mV mV mV µs dB dB dB ± 1.0 LEVEL SIGNAL DETECT (SDOUT) Level Detect Range (See Figure 2) RTHRESH = 2 kΩ RTHRESH = 20 kΩ RTHRESH = 90 kΩ Response TimeDC-Coupled RTHRESH = 2 kΩ Hysteresis (Electrical), PRBS 223 RTHRESH = 20 kΩ RTHRESH = 90 kΩ LOSS OF LOCK DETECT (LOL) LOL Response Time Typ 9.4 2.5 0.7 0.1 5.6 3.9 3.2 From fVCO error > 1000 ppm 13.3 5.3 3.0 0.3 6.6 6.1 6.7 µs 60 POWER SUPPLY VOLTAGE 3.0 3.3 3.6 V POWER SUPPLY CURRENT 150 164 215 mA 590 0.025 880 kHz dB UI rms UI p-p PHASE-LOCKED LOOP CHARACTERISTICS Jitter Transfer BW Jitter Peaking Jitter Generation PIN–NIN = 10 mV p-p OC-48 OC-48 OC-48, 12 kHz–20 MHz 0.05 Jitter Tolerance OC-48 (See Figure 9) 600 Hz 6 kHz 100 kHz 1 MHz 923 203 5.5 1.03 –2– 0.0033 0.09 UI p-p UI p-p UI p-p UI p-p REV. A ADN2811 Parameter Conditions CML OUTPUTS (CLKOUTP/N, DATAOUTP/N) Single-Ended Output Swing VSE (See Figure 3) Differential Output Swing VDIFF (See Figure 3) Output High Voltage VOH Output Low Voltage VOL Rise Time 20%–80% Fall time 80%–20% Setup Time TS (See Figure 1) OC-48 Hold Time TH (See Figure 1) OC-48 REFCLK DC INPUT CHARACTERISTICS Input Voltage Range @ REFCLKP or REFCLKN Peak-to-Peak Differential Input Common-Mode Level DC-Coupled, Single-Ended TEST DATA DC INPUT CHARACTERISTICS4 (TDINP/N) Peak-to-Peak Differential Input Voltage Min Typ Max Unit 300 600 455 910 VCC 600 1200 mV mV V V ps ps VCC – 0.6 84 84 140 ps 150 ps 0 100 VCC VCC/2 V mV V 0.8 V CML Inputs LVTTL DC INPUT CHARACTERISTICS Input High Voltage VIH Input Low Voltage VIL Input Current VIN = 0.4 V or VIN = 2.4 V LVTTL DC OUTPUT CHARACTERISTICS Output High Voltage VOH, IOH = –2.0 mA Output Low Voltage VOL, IOL = +2.0 mA 2.0 –5 –3– 0.8 +5 2.4 NOTES 1 PIN and NIN should be differentially driven, ac-coupled for optimum sensitivity. 2 PWD measurement made on quantizer outputs in BYPASS mode. 3 Measurement is equipment limited. 4 TDINP/N are CML inputs. If the drivers to the TDINP/N inputs are anything other than CML, they must be ac-coupled. Specifications subject to change without notice. REV. A VCC – 0.3 150 150 0.4 V V V V ADN2811 ABSOLUTE MAXIMUM RATINGS* THERMAL CHARACTERISTICS Supply Voltage (VCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.5 V Minimum Input Voltage (All Inputs) . . . . . . . . . . VEE – 0.4 V Maximum Input Voltage (All Inputs) . . . . . . . . VCC + 0.4 V Maximum Junction Temperature . . . . . . . . . . . . . . . . . 165C Storage Temperature . . . . . . . . . . . . . . . . . . –65C to +150C Lead Temperature (Soldering 10 Sec) . . . . . . . . . . . . . . 300C Thermal Resistance 48-Lead LFCSP, four-layer board with exposed paddle soldered to VCC θJA = 25C/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. ORDERING GUIDE Model Temperature Range ADN2811ACP-CML –40ºC to +85ºC ADN2811ACP-CML-RL –40ºC to +85ºC Package Option 48-Lead LFCSP CP-48 48-Lead LFCSP CP-48 Tape-Reel, 2500 pcs CAUTION ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the human body and test equipment and can discharge without detection. Although the ADN2811 features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. –4– REV. A ADN2811 48 LOOPEN 47 VCC 46 VEE 45 SDOUT 44 BYPASS 43 VEE 42 VEE 41 CLKOUTP 40 CLKOUTN 39 SQUELCH 38 DATAOUTP 37 DATAOUTN PIN CONFIGURATION NC = NO CONNECT PIN 1 INDICATOR ADN2811 TOP VIEW 36 VCC 35 VCC 34 VEE 33 VEE 32 NC 31 NC 30 RATE 29 VEE 28 VCC 27 VEE 26 VCC 25 CF2 REFCLKN 13 REFCLKP 14 REFSEL 15 VEE 16 TDINP 17 TDINN 18 VEE 19 VCC 20 CF1 21 VEE 22 REFSEL1 23 REFSEL0 24 THRADJ 1 VCC 2 VEE 3 VREF 4 PIN 5 NIN 6 SLICEP 7 SLICEN 8 VEE 9 LOL 10 XO1 11 XO2 12 PIN FUNCTION DESCRIPTION Pin No. 1 2, 26, 28, Pad 3, 9, 16, 19, 22, 27, 29, 33, 34, 42, 43, 46 4 5 6 7 8 10 11 12 13 Mnemonic THRADJ VCC VEE Type AI P P Description LOS Threshold Setting Resistor Analog Supply Ground VREF PIN NIN SLICEP SLICEN LOL XO1 XO2 REFCLKN AO AI AI AI AI DO AO AO DI 14 REFCLKP DI 15 REFSEL DI 17 18 20, 47 21 23 24 25 30 31, 32 35, 36 37 38 39 40 41 44 45 48 TDINP TDINN VCC CF1 REFSEL1 REFSEL0 CF2 RATE NC VCC DATAOUTN DATAOUTP SQUELCH CLKOUTN CLKOUTP BYPASS SDOUT LOOPEN AI AI P AO DI DI AO DI DI P DO DO DI DO DO DI DO DI Internal VREF Voltage. Decouple to GND with 0.1 µF capacitor. Differential Data Input. CML. Differential Data Input. CML. Differential Slice Level Adjust Input Differential Slice Level Adjust Input Loss of Lock Indicator. LVTTL active high. Crystal Oscillator Crystal Oscillator Differential REFCLK Input. LVTTL, LVCMOS, LVPECL, LVDS (LVPECL, LVDS only at 155.52 MHz). Differential REFCLK Input. LVTTL, LVCMOS, LVPECL, LVDS (LVPECL, LVDS only at 155.52 MHz). Reference Source Select. “0” = on-chip oscillator with external crystal; “1” = external clock source, LVTTL. Differential Test Data Input Differential Test Data Input Digital Supply Frequency Loop Capacitor Reference Frequency Select (See Table II) LVTTL. Reference Frequency Select (See Table II) LVTTL. Frequency Loop Capacitor Data Rate Select (See Table I) LVTTL. No Connect Output Driver Supply Differential Retimed Data Output. CML. Differential Retimed Data Output. CML. Disable Clock and Data Outputs. Active high. LVTTL. Differential Recovered Clock Output. CML. Differential Recovered Clock Output. CML. Bypass CDR Mode. Active high. LVTTL. Loss of Signal Detect Output. Active high. LVTTL. Enable Test Data Inputs. Active high. LVTTL. Type: P = Power, AI = Analog Input, AO = Analog Output, DI = Digital Input, DO = Digital Output REV. A –5– ADN2811 CLKOUTP TH TS DATAOUTP/N Figure 1. Output Timing 18 THRADJ RESISTOR VS. LOS TRIP POINT 16 14 mV 12 10 8 6 4 2 0 0 10 20 30 40 50 60 RESISTANCE – k⍀ 70 80 90 100 Figure 2. LOS Comparator Trip Point Programming OUTP VCML VSE OUTN OUTP–OUTN VSE VDIFF 0V Figure 3. Single-Ended vs. Differential Output Specs –6– REV. A ADN2811 DEFINITION OF TERMS Maximum, Minimum, and Typical Specifications SINGLE-ENDED VS. DIFFERENTIAL AC-coupling is typically used to drive the inputs to the quantizer. The inputs are internally dc biased to a common-mode potential of ~0.6 V. Driving the ADN2811 single-ended and observing the quantizer input with an oscilloscope probe at the point indicated in Figure 5 shows a binary signal with an average value equal to the common-mode potential and instantaneous values both above and below the average value. It is convenient to measure the peak-to-peak amplitude of this signal and call the minimum required value the quantizer sensitivity. Referring to Figure 4, since both positive and negative offsets need to be accommodated, the sensitivity is twice the overdrive. Specifications for every parameter are derived from statistical analyses of data taken on multiple devices from multiple wafer lots. Typical specifications are the mean of the distribution of the data for that parameter. If a parameter has a maximum (or a minimum), that value is calculated by adding to (or subtracting from) the mean six times the standard deviation of the distribution. This procedure is intended to tolerate production variations. If the mean shifts by 1.5 standard deviations, the remaining 4.5 standard deviations still provide a failure rate of only 3.4 parts per million. For all tested parameters, the test limits are guardbanded to account for tester variation to thus guarantee that no device is shipped outside of data sheet specifications. 10mV p-p VREF INPUT SENSITIVITY AND INPUT OVERDRIVE SCOPE PROBE Sensitivity and overdrive specifications for the quantizer involve offset voltage, gain, and noise. The relationship between the logic output of the quantizer and the analog voltage input is shown in Figure 4. For sufficiently large positive input voltage, the output is always Logic 1; similarly for negative inputs, the output is always Logic 0. However, the transitions between output Logic Levels 1 and 0 are not at precisely defined input voltage levels but occur over a range of input voltages. Within this zone of confusion, the output may be either 1 or 0, or it may even fail to attain a valid logic state. The width of this zone is determined by the input voltage noise of the quantizer. The center of the zone of confusion is the quantizer input offset voltage. Input overdrive is the magnitude of signal required to guarantee the correct logic level with 1 × 10–10 confidence level. ADN2811 PIN + QUANTIZER 50 50 VREF Figure 5. Single-Ended Sensitivity Measurement 5mV p-p VREF OUTPUT SCOPE PROBE NOISE 1 ADN2811 PIN + QUANTIZER NIN 0 OFFSET 50 INPUT (V p-p) 50 VREF OVERDRIVE SENSITIVITY (2 OVERDRIVE) Figure 6. Differential Sensitivity Measurement Figure 4. Input Sensitivity and Input Overdrive Driving the ADN2811 differentially (see Figure 6), sensitivity seems to improve by observing the quantizer input with an oscilloscope probe. This is an illusion caused by the use of a single-ended probe. A 5 mV p–p signal appears to drive the ADN2811 quantizer. However, the single-ended probe measures only half the signal. The true quantizer input signal is twice this value since the other quantizer input is a complementary signal to the signal being observed. LOS Response Time The LOS response time is the delay between the removal of the input signal and the indication of loss of signal (LOS) at SDOUT. The LOS response time of the ADN2811 is 300 ns typ when the inputs are dc-coupled. In practice, the time constant of the ac-coupling at the quantizer input determines the LOS response time. REV. A –7– ADN2811 JITTER SPECIFICATIONS Jitter Tolerance The ADN2811 CDR is designed to achieve the best bit-error-rate (BER) performance and has exceeded the jitter generation, transfer, and tolerance specifications proposed for SONET/SDH equipment defined in the Telcordia Technologies specification. The jitter tolerance is defined as the peak-to-peak amplitude of the sinusoidal jitter applied on the input signal that causes a 1 dB power penalty. This is a stress test that is intended to ensure no additional penalty is incurred under the operating conditions (see Figure 8). Figure 9 shows the typical OC-48 jitter tolerance performance of the ADN2811. INPUT JITTER AMPLITUDE – UI p-p Jitter is the dynamic displacement of digital signal edges from their long-term average positions measured in UI (unit intervals), where 1 UI = 1 bit period. Jitter on the input data can cause dynamic phase errors on the recovered clock sampling edge. Jitter on the recovered clock causes jitter on the retimed data. The following section briefly summarizes the specifications of the jitter generation, transfer, and tolerance in accordance with the Telcordia document (GR-253-CORE, Issue 3, September 2000) for the optical interface at the equipment level and the ADN2811 performance with respect to those specifications. Jitter Generation The jitter generation specification limits the amount of jitter that can be generated by the device with no jitter and wander applied at the input. For OC-48 devices, the band-pass filter has a 12 kHz high-pass cutoff frequency with a roll-off of 20 dB/ decade and a low-pass cutoff frequency of at least 20 MHz. The jitter generated should be less than 0.01 UI rms and less than 0.1 UI p-p. 15 SLOPE = –20dB/DECADE 1.5 0.15 f0 f1 f2 f3 f4 JITTER FREQUENCY – Hz Figure 8. SONET Jitter Tolerance Mask 1.00E+02 Jitter Transfer ADN2811 AMPLITUDE – UI p-p The jitter transfer function is the ratio of the jitter on the output signal to the jitter applied on the input signal versus the frequency. This parameter measures the limited amount of jitter on an input signal that can be transferred to the output signal (see Figure 7). 1.00E+01 1.00E+00 OC-48 SONET MASK JITTER GAIN – dB 0.1 1.00E–01 1.00E+00 SLOPE = –20dB/DECADE ACCEPTABLE RANGE 1.00E+02 1.00E+04 1.00E+06 1.00E+01 1.00E+03 1.00E+05 1.00E+07 MODULATION FREQUENCY – Hz Figure 9. OC-48 Jitter Tolerance Curve fC JITTER FREQUENCY – kHz Figure 7. Jitter Transfer Curve –8– REV. A ADN2811 The error transfer, e(s)/X(s), has the same high-pass form as an ordinary phase-locked loop. This transfer function is free to be optimized to give excellent wideband jitter accommodation since the jitter transfer function, Z(s)/X(s), provides the narrowband jitter filtering. THEORY OF OPERATION The ADN2811 is a delay-locked and phase-locked loop circuit for clock recovery and data retiming from an NRZ encoded data stream. The phase of the input data signal is tracked by two separate feedback loops that share a common control voltage. A high speed delay-locked loop path uses a voltage controlled phase shifter to track the high frequency components of the input jitter. A separate phase control loop, comprised of the VCO, tracks the low frequency components of the input jitter. The initial frequency of the VCO is set by yet a third loop, which compares the VCO frequency with the reference frequency and sets the coarse tuning voltage. The jitter tracking phase-locked loop controls the VCO by the fine tuning control. The delay-locked and phase-locked loops contribute to overall jitter accommodation. At low frequencies of input jitter on the data signal, the integrator in the loop filter provides high gain to track large jitter amplitudes with small phase error. In this case, the VCO is frequency modulated and jitter is tracked as in an ordinary phase-locked loop. The amount of low frequency jitter that can be tracked is a function of the VCO tuning range. A wider tuning range gives larger accommodation of low frequency jitter. The internal loop control voltage remains small for small phase errors, so the phase shifter remains close to the center of its range and thus contributes little to the low frequency jitter accommodation. The delay-locked and phase-locked loops together track the phase of the input data signal. For example, when the clock lags input data, the phase detector drives the VCO to a higher frequency and also increases the delay through the phase shifter. Both of these actions both serve to reduce the phase error between the clock and data. The faster clock picks up phase while the delayed data loses phase. Since the loop filter is an integrator, the static phase error will be driven to zero. At medium jitter frequencies, the gain and tuning range of the VCO are not large enough to track the input jitter. In this case, the VCO control voltage becomes large and saturates, and the VCO frequency dwells at one or the other extreme of its tuning range. The size of the VCO tuning range therefore has only a small effect on the jitter accommodation. The delay-locked loop control voltage is now larger, and so the phase shifter takes on the burden of tracking the input jitter. The phase shifter range, in UI, can be seen as a broad plateau on the jitter tolerance curve. The phase shifter has a minimum range of 2 UI at all data rates. Another view of the circuit is that the phase shifter implements the zero required for the frequency compensation of a secondorder phase-locked loop, and this zero is placed in the feedback path and thus does not appear in the closed-loop transfer function. Jitter peaking in a conventional second-order phase-locked loop is caused by the presence of this zero in the closed-loop transfer function. Since this circuit has no zero in the closedloop transfer, jitter peaking is minimized. The gain of the loop integrator is small for high jitter frequencies, so larger phase differences are needed to make the loop control voltage big enough to tune the range of the phase shifter. Large phase errors at high jitter frequencies cannot be tolerated. In this region, the gain of the integrator determines the jitter accommodation. Since the gain of the loop integrator declines linearly with frequency, jitter accommodation is lower with higher jitter frequency. At the highest frequencies, the loop gain is very small and little tuning of the phase shifter can be expected. In this case, jitter accommodation is determined by the eye opening of the input data, the static phase error, and the residual loop jitter generation. The jitter accommodation is roughly 0.5 UI in this region. The corner frequency between the declining slope and the flat region is the closed loop bandwidth of the delay-locked loop, which is roughly 5 MHz. The delay-locked and phase-locked loops together simultaneously provide wideband jitter accommodation and narrow-band jitter filtering. The linearized block diagram in Figure 10 shows the jitter transfer function, Z(s)/X(s), is a second-order low-pass providing excellent filtering. Note the jitter transfer has no zero, unlike an ordinary second-order phase-locked loop. This means that the main PLL loop has low jitter peaking (see Figure 11), which makes this circuit ideal for signal regenerator applications where jitter peaking in a cascade of regenerators can contribute to hazardous jitter accumulation. psh INPUT DATA X(s) e(s) d/sc o/s JITTER PEAKING IN ORDINARY PLL Z(s) RECOVERED CLOCK d = PHASE DETECTOR GAIN o = VCO GAIN c = LOOP INTEGRATOR psh = PHASE SHIFTER GAIN n = DIVIDE RATIO JITTER GAIN (dB) JITTER TRANSFER FUNCTION Z(s) 1 = cn n psh X(s) +s +1 s2 do o ADN2811 Z(s) X(s) TRACKING ERROR TRANSFER FUNCTION e(s) = X(s) s2 + s s2 d psh do + c cn o n psh f (kHz) Figure 11. Jitter Response vs. Conventional PLL Figure 10. PLL/DLL Architecture REV. A d psh c –9– ADN2811 FUNCTIONAL DESCRIPTION Clock and Data Recovery The ADN2811 will recover clock and data from serial bit streams at OC-48 as well as the 15/14 FEC rates. The data rate is selected by the RATE input (see Table I). Table I. Data Rate Selection RATE Data Rate Frequency (MHz) 0 1 OC-48 OC-48 FEC 2488.32 2666.06 LVDS levels via the REFCLKN/P inputs, independent of data rate. The input buffer accepts any differential signal with a peak-to-peak differential amplitude of greater than 100 mV (e.g., LVPECL or LVDS) or a standard single-ended low voltage TTL input, providing maximum system flexibility. The appropriate division ratio can be selected using the REFSEL0/1 pins, according to Table II. Phase noise and duty cycle of the reference clock are not critical and 100 ppm accuracy is sufficient. ADN2811 REFCLKP Limiting Amplifier BUFFER The limiting amplifier has differential inputs (PIN/NIN) that are internally terminated with 50 Ω to an on-chip voltage reference (VREF = 0.6 V typically). These inputs are normally ac-coupled, although dc-coupling is possible as long as the input common-mode voltage remains above 0.4 V (see Figures 20–22). Input offset is factory trimmed to achieve better than 4 mV typical sensitivity with minimal drift. The limiting amplifier can be driven differentially or single-ended. REFCLKN 100k 100k VCC/2 XO1 VCC XO2 VCC Slice Adjust The quantizer slicing level can be offset by ± 100 mV to mitigate the effect of ASE (amplified spontaneous emission) noise by applying a differential voltage input of ± 0.8 V to SLICEP/N inputs. If no adjustment of the slice level is needed, SLICEP/N should be tied to VCC. Loss of Signal (LOS) Detector VCC CRYSTAL OSCILLATOR REFSEL Figure 12. Differential REFCLK Configuration ADN2811 VCC REFCLKP The receiver front end level signal detect circuit indicates when the input signal level has fallen below a user adjustable threshold. The threshold is set with a single external resistor from Pin 1, THRADJ, to GND. The LOS comparator trip point versus the resistor value is illustrated in Figure 2 (this is only valid for SLICEP = SLICEN = VCC). If the input level to the ADN2811 drops below the programmed LOS threshold, SDOUT (Pin 45) will indicate the loss of signal condition with a Logic 1. The LOS response time is ~300 ns by design but will be dominated by the RC time constant in ac-coupled applications. CLK OSC OUT BUFFER NC REFCLKN 100k 100k VCC/2 XO1 VCC XO2 VCC VCC If the LOS detector is used, the quantizer slice adjust pins must both be tied to VCC. This is to avoid interaction with the LOS threshold level. CRYSTAL OSCILLATOR REFSEL Figure 13. Single-Ended REFCLK Configuration Note that it is not expected to use both LOS and slice adjust at the same time; systems with optical amplifiers need the slice adjust to evade ASE. However, a loss of signal in an optical link that uses optical amplifiers causes the optical amplifier output to be full-scale noise. Under this condition, the LOS would not detect the failure. In this case, the loss of lock signal will indicate the failure because the CDR circuitry will not be able to lock onto a signal that is full-scale noise. ADN2811 VCC REFCLKP BUFFER NC REFCLKN 100k 100k VCC/2 Reference Clock There are three options for providing the reference frequency to the ADN2811: differential clock, single-ended clock, or crystal oscillator. See Figures 12–14 for example configurations. XO1 19.44MHz The ADN2811 can accept any of the following reference clock frequencies: 19.44 MHz, 38.88 MHz, 77.76 MHz at LVTTL/ LVCMOS/LVPECL/LVDS levels or 155.52 MHz at LVPECL/ XO2 CRYSTAL OSCILLATOR REFSEL Figure 14. Crystal Oscillator Configuration –10– REV. A ADN2811 LOL An on-chip oscillator to be used with an external crystal is also provided as an alternative to using the REFCLKN/P inputs. Details of the recommended crystal are given in Table III. 1 Table II. Reference Frequency Selection REFSEL REFSEL[1..0] 1 1 1 1 0 00 01 10 11 XX 1000 Applied Reference Frequency (MHz) Mode Frequency/Overall Stability Frequency Accuracy Temperature Stability Aging ESR Series Resonant 19.44 MHz ± 100 ppm ± 100 ppm ± 100 ppm ± 100 ppm 20 Ω max REV. A fVCO ERROR (ppm) Parameter Value Temperature Range Capacitance Leakage Rating –40C to +85C >3.0 µF <80 nA >6.3 V Recommended Manufacturer: Murata Electronics (770) 436-1300 Part Number: GRM32RR71C475LC01 Squelch Mode When the squelch input is driven to a TTL high state, both the clock and data outputs are set to the zero state to suppress downstream processing. If desired, this pin can be directly driven by the LOS detector output, SDOUT. If the squelch function is not required, the pin should be tied to VEE. Test Modes: Bypass and Loopback REFSEL must be tied to VCC when the REFCLKN/P inputs are active or tied to VEE when the oscillator is used. No connection between the XO pin and REFCLK input is necessary (see Figures 12–14). Note that the crystal should operate in series resonant mode, which renders it insensitive to external parasitics. No trimming capacitors are required. The lock detector monitors the frequency difference between the VCO and the reference clock and deasserts the loss of lock signal when the VCO is within 500 ppm of center frequency (see Figure 15). This enables the phase loop, which pulls the VCO frequency in the remaining amount and also acquires phase lock. Once locked, if the input frequency error exceeds 1000 ppm (0.1%), the loss of lock signal is reasserted and control returns to the frequency loop, which will reacquire and maintain a stable clock signal at the output. 1000 Table IV. Recommended CF Capacitor Specification Recommended Manufacturer: Raltron (305) 593-6033 Part Number: H10S-19.440-S-EXT Lock Detector Operation 500 The frequency loop requires a single external capacitor between CF1 and CF2. The capacitor specification is given in Table IV. Table III. Required Crystal Specifications Value 0 Figure 15. Transfer Function of LOL 19.44 38.88 77.76 155.52 REFCLKP/N Inactive. Use 19.44 MHz XTAL oscillator on Pins XO1, XO2 (Pull REFCLKP to VCC). Parameter 500 When the bypass input is driven to a TTL high state, the quantizer output is connected directly to the buffers driving the data out pins, thus bypassing the clock recovery circuit (see Figure 16). This feature can help the system to deal with nonstandard bit rates. The Loopback Mode can be invoked by driving the LOOPEN Pin to a TTL high state, which facilitates system diagnostic testing. This will connect the test inputs (TDINP/N) to the clock and data recovery circuit (per Figure 16). The test inputs have internal 50 Ω terminations and can be left floating when not in use. TDINP/N are CML inputs and can only be dc-coupled when being driven by CML outputs. The TDINP/N inputs must be ac-coupled if being driven by anything other than CML outputs. Bypass and loopback modes are mutually exclusive. Only one of these modes can be used at any given time. The ADN2811 will be put into an indeterminate state if both BYPASS and LOOPEN pins are set to Logic 1 at the same time. –11– ADN2811 ADN2811 PIN + 0 QUANTIZER NIN CDR 50⍀ 50⍀ VREF FROM QUANTIZER OUTPUT 1 1 50⍀ RETIMED DATA CLK 0 50⍀ VCC TDINP/N LOOPEN BYPASS DATAOUTP/N CLKOUTP/N SQUELCH Figure 16. Test Modes CLKOUTP/N and DATAOUTP/N output traces are matched in length. All high speed CML outputs, CLKOUTP/N and DATAOUTP/N, also require 100 Ω back termination chip resistors connected between the output pin and VCC. These resistors should be placed as close as possible to the output pins. These 100 Ω resistors are in parallel with on-chip 100 Ω termination resistors to create a 50 Ω back termination (see Figure 18). APPLICATIONS INFORMATION PCB Design Guidelines Proper RF PCB design techniques must be used for optimal performance. Power Supply Connections and Ground Planes Use of one low impedance ground plane to both analog and digital grounds is recommended. The VEE pins should be soldered directly to the ground plane to reduce series inductance. If the ground plane is an internal plane and connections to the ground plane are made through vias, multiple vias may be used in parallel to reduce the series inductance, especially on Pins 33 and 34, which are the ground returns for the output buffers. Use of a 10 µF electrolytic capacitor between VCC and GND is recommended at the location where the 3.3 V supply enters the PCB. Use of 0.1 µF and 1 nF ceramic chip capacitors should be placed between IC power supply VCC and GND as close as possible to the ADN2811 VCC pins. Again, if connections to the supply and ground are made through vias, the use of multiple vias in parallel will help to reduce series inductance, especially on Pins 35 and 36, which supply power to the high speed CLKOUTP/N and DATAOUTP/N output buffers. Refer to the schematic in Figure 17 for recommended connections. Transmission Lines Use of 50 Ω transmission lines are required for all high frequency input and output signals to minimize reflections, including PIN, NIN, CLKOUTP, CLKOUTN, DATAOUTP, and DATAOUTN (also REFCLKP, REFCLKN for a 155.2 MHz REFCLK). It is also recommended that the PIN/NIN input traces are matched in length and that the The high speed inputs, PIN and NIN, are internally terminated with 50 Ω to an internal reference voltage (see Figure 19). A 0.1 µF capacitor is recommended between VREF, Pin 4, and GND to provide an ac ground for the inputs. As with any high speed mixed-signal design, take care to keep all high speed digital traces away from sensitive analog nodes. Soldering Guidelines for Chip-Scale Package The lands on the 48-lead LFCSP are rectangular. The printed circuit board pad for these should be 0.1 mm longer than the package land length and 0.05 mm wider than the package land width. The land should be centered on the pad. This will ensure that the solder joint size is maximized. The bottom of the chipscale package has a central exposed pad. The pad on the printed circuit board should be at least as large as this exposed pad. The user must connect the exposed pad to analog VCC. If vias are used, they should be incorporated into the pad at 1.2 mm pitch grid. The via diameter should be between 0.3 mm and 0.33 mm and the via barrel should be plated with 1 oz. copper to plug the via. –12– REV. A ADN2811 VCC 50 TRANSMISSION LINES 4 100 CLKOUTP VCC CLKOUTN C DATAOUTP 10F 1nF DATAOUTN DATAOUTP SQUELCH CLKOUTN CLKOUTP VEE VEE BYPASS SDOUT VCC VEE DATAOUTN LOOPEN 0.1F 48 47 46 45 44 43 42 41 40 39 38 37 RTH THRADJ VCC VCC 1nF 0.1F 0.1F 50 VEE VREF PIN TIA NIN 50 SLICEP CIN VCC SLICEN VEE LOL C XO1 19.44MHz XO2 1 36 2 35 3 34 4 33 EXPOSED PAD TIED OFF TO VCC PLANE WITH VIAS 5 6 32 31 7 30 8 29 28 9 0.1F 1nF 10 11 27 26 ADN2811 25 12 VCC VCC VCC 0.1F 1nF VEE VEE NC NC RATE C VEE VCC 0.1F 1nF VEE VCC VCC CF2 4.7F (SEE TABLE IV FOR SPECS) C REFSEL0 C REFSEL1 VEE CF1 VCC VEE NC TDINN TDINP NC VEE REFSEL REFCLKP VCC NC REFCLKN 13 14 15 16 17 18 19 20 21 22 23 24 VCC 0.1F 1nF Figure 17. Typical Application Circuit VCC VCC VCC ADN2811 VTERM 100 100 100 100 0.1F 0.1F 50 50 TIA 50 CIN 50 CIN PIN NIN 50 50 50 50 ADN2811 VTERM 0.1F Figure 18. AC-Coupled Output Configuration REV. A VREF Figure 19. AC-Coupled Input Configuration –13– ADN2811 Choosing AC-Coupling Capacitors DC-Coupled Application The choice of ac-coupling capacitors at the input (PIN, NIN) and output (DATAOUTP, DATAOUTN) of the ADN2811 must be chosen carefully. When choosing the capacitors, the time constant formed with the two 50 Ω resistors in the signal path must be considered. When a large number of consecutive identical digits (CIDs) are applied, the capacitor voltage can drop due to baseline wander (see Figure 20), causing pattern dependent jitter (PDJ). The inputs to the ADN2811 can also be dc-coupled. This may be necessary in burst mode applications where there are long periods of CIDs and baseline wander cannot be tolerated. If the inputs to the ADN2811 are dc-coupled, care must be taken not to violate the input range and common-mode level requirements of the ADN2811 (see Figures 21–23). If dc-coupling is required, and the output levels of the TIA do not adhere to the levels shown in Figures 22 and 23, then there will need to be level shifting and/or an attenuator between the TIA outputs and the ADN2811 inputs. For the ADN2811 to work robustly at OC-48, a minimum capacitor of 0.1 µF to PIN/NIN and 0.1 µF on DATAOUTP/ DATAOUTN should be used. This is based on the assumption that 1000 CIDs must be tolerated and that the PDJ should be limited to 0.01 UI p-p. V1 ADN2811 CIN V2 PIN 50 VREF TIA V1b CIN V2b COUT + DATAOUTP LIMAMP CDR COUT 50 DATAOUTN NIN 1 2 3 4 V1 V1b V2 VREF V2b VTH VDIFF VDIFF = V2–V2b VTH = ADN2811 QUANTIZER THRESHOLD NOTES 1. DURING DATA PATERNS WITH HIGH TRANSITION DENSITY, DIFFERENTIAL DC VOLTAGE AT V1 AND V2 IS ZERO. 2. WHEN THE OUTPUT OF THE TIA GOES TO CID, V1 AND V1b ARE DRIVEN TO DIFFERENT DC LEVELS. V2 AND V2b DISCHARGE TO THE V REF LEVEL, WHICH EFFECTIVELY INTRODUCES A DIFFERENTIAL DC OFFSET ACROSS THE AC-COUPLING CAPACITORS. 3. WHEN THE BURST OF DATA STARTS AGAIN, THE DIFFERENTIAL DC OFFSET ACROSS THE AC-COUPLING CAPACITORS IS APPLIED TO THE INPUT LEVELS, CAUSING A DC SHIFT IN THE DIFFERENTIAL INPUT. THIS SHIFT IS LARGE ENOUGH SUCH THAT ONE OF THE STATES, EITHER HIGH OR LOW DEPENDING ON THE LEVELS OF V1 AND V1b WHEN THE TIA WENT TO CID, IS CANCELLED OUT. THE QUANTIZER WILL NOT RECOGNIZE THIS AS A VALID STATE. 4. THE DC OFFSET SLOWLY DISCHARGES UNTIL THE DIFFERENTIAL INPUT VOLTAGE EXCEEDS THE SENSITIVITY OF THE ADN2811. THE QUANTIZER WILL BE ABLE TO RECOGNIZE BOTH HIGH AND LOW STATES AT THIS POINT. Figure 20. Example of Baseline Wander –14– REV. A ADN2811 VCC INPUT (V) ADN2811 50 PIN V p-p = PIN – NIN = 2 VSE = 10mV AT SENSITIVITY TIA 50 PIN NIN 50 0.1F VSE = 5mV MIN VCM = 0.4V MIN (DC-COUPLED) NIN 50 VREF Figure 22. Minimum Allowed DC-Coupled Input Levels Figure 21. ADN2811 with DC-Coupled Inputs INPUT (V) V p-p = PIN – NIN = 2 VSE = 2.4V MAX LOL Toggling during Loss of Input Data PIN If the input data stream is lost due to a break in the optical link (or for any reason), the clock output from the ADN2811 will stay within 1000 ppm of the VCO center frequency as long as there is a valid reference clock. The LOL pin will toggle at a rate of several kHz. This is because the LOL pin will toggle between a Logic 1 and a Logic 0 while the frequency loop and phase loop swap control of the VCO. The chain of events are as follows: VSE = 1.2V MAX VCM = 0.6V (DC-COUPLED) NIN • The ADN2811 is locked to the input data stream; LOL = 0. • The input data stream is lost due to a break in the link. The VCO frequency drifts until the frequency error is greater than 1000 ppm. LOL is asserted to a Logic 1 as control of the VCO is passed back to the frequency loop. • The frequency loop pulls the VCO to within 500 ppm of its center frequency. Control of the VCO is passed back to the phase loop and LOL is deasserted to a Logic 0. • The phase loop tries to acquire, but there is no input data present so the VCO frequency drifts. • The VCO frequency drifts until the frequency error is greater than 1000 ppm. LOL is asserted to a Logic 1 as control of the VCO is passed back to the frequency loop. This process is repeated until a valid input data stream is re-established. REV. A –15– Figure 23. Maximum Allowed DC-Coupled Input Levels ADN2811 OUTLINE DIMENSIONS 48-Lead Frame Chip Scale Package [LFCSP] 7 mm 7 mm Body (CP-48) 7.00 BSC SQ 0.60 MAX 0.60 MAX 37 6.75 BSC SQ TOP VIEW 0.20 REF 12 MAX 1 5.25 5.10 SQ 4.95 BOTTOM VIEW 0.50 0.40 0.30 1.00 0.90 0.80 PIN 1 INDICATOR 48 36 PIN 1 INDICATOR 0.30 0.23 0.18 C03019–0–12/02(A) Dimensions shown in millimeters 25 24 12 13 5.50 REF 1.00 MAX 0.65 NOM 0.05 MAX 0.02 NOM 0.50 BSC SEATING PLANE COPLANARITY 0.08 COMPLIANT TO JEDEC STANDARDS MO-220-VKKD-2 Revision History Location Page 12/02—Data Sheet changed from REV. 0 to REV. A. Change to FUNCTIONAL DESCRIPTION Reference Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 PRINTED IN U.S.A. Updated OUTLINE DIMENSIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 –16– REV. A