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M02095G-12

M02095G-12

  • 厂商:

    AEROFLEX

  • 封装:

    TQFN32

  • 描述:

    ICLASERDRVR1.25GBPSAMP

  • 数据手册
  • 价格&库存
M02095G-12 数据手册
M02095/6 3.3/5V Laser Driver / Limiting Amplifier for Operation to 2.5 Gbps The M02095 and M02096 are integrated laser drivers and limiting amplifiers for applications to 1.25 Gbps and 2.5 Gbps, respectively. The laser driver modulation output can be AC or DC coupled to an FP/DFB laser. The devices can operate from a 3.3V or 5V supply. The devices include monitors for bias and laser power. Integrated safety circuitry provides latched bias and modulation current shutdown if a fault condition is detected and provides an internal VCC switch. The limiting amplifier also includes a programmable signal-level detector, allowing the user to set thresholds at which the logic outputs are enabled. PECL or CML outputs are available on the limiting amplifier. Configuration logic provides flexibility in setting data path polarity, safety logic configuration, and LOS behavior. Applications Features (con’t) • • • • • • • • Integrated power supply switch for redundant shutdown under a fault condition • Temperature compensation for modulation current • Automatic Power Control • SFP compliant safety circuitry (configurable) • 3.3 mV typical input limiting amp sensitivity at 2.5 Gbps • CML or PECL limiting amplifier outputs • Limiting amplifier includes integrated DC offset cancellation circuit • Polarity Control for both the driver and limiting amplifier data paths • Operates with 3.3V or 5V supply with an internal auto-sensing regulator that enables with 5V supplies and is bypassed with 3.3V supplies • Powers 3.3V ROSAs from its Receiver Regulator output enabling true 3.3/5V designs using all 3.3V Mindspeed TIAs 2.5 Gbps STM-16/OC-48 SDH/SONET (M02096) 1.06 and 2.12 Gbps Fibre Channel (M02095/6) 1.25 Gbps Ethernet (M02095/6) 1.25 Gbps SDH/SONET (M02095/6) 2.67 Gbps SDH/SONET with FEC (M02096) SDH/SONET 155 Mbps Transceivers FTTx and Media Converters Features • High speed operation; suitable for applications to 2.5 Gbps. 55 ps typical rise/fall time into 25Ω • Independently programmable bias and modulation currents Modulation current to 85 mA and bias current to 100 mA M02095/6 Typical Applications Diagram VCC VCC3R VCCR STSET RxOUTp Clock Data Recovery Unit V CC3R Threshold Setting Circuit Regulator AC-Coupled RxINp to TIA Output Buffer RxOUTm 2kΩ Limiting Amplifier Vttr 2kΩ RxINm M0201x Photodiode Rx_Polarity LOS-ST AC or DC Coupled (as described in Applications Information) Offset Cancel LOS Level Detect Comparator LOS-to-JAM DCR_Disable VCC T To Safety Logic 3.3V Regulator with Bypass TCSTART To Safety Logic Modulation Control TCSLOPE Iref RSSI LOS-ST_sel VCC Biasing VCC3T SVCC MODSET OUT- DIN + DeMux Output 4kΩ DIN - Vttx 4kΩ Rx_Polarity Tx_Polarity CONFIG_2 CONFIG_3 Configuration Logic LOS-ST_sel OUT+ GND0 BIAS_Mon Analog MUX VCC VCC3 TxPwrMon DCR_Disable LOS-to-JAM CONFIG_4 GND Laser Driver Tx_Polarity CONFIG_1 Configuration Control (V CC, GND or Float) Output Buffer Input Buffer IBOUT SCB Safety Circuitry with Latched Fault TX Disable Laser Power Control IPIN BIASMON TxPwrMON APCSET CAPC FAIL DIS RESET VCC 3T 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential August 2007 Ordering Information Part Number Package Operating Temperature M02095G-XX* QFN32 –40°C to 95°C M02096G-XX* QFN32 –40°C to 95°C * The letter “G” designator after the part number indicates that the device is RoHS-compliant. Refer to www.mindspeed.com for additional information. Revision History Revision Level Date ASIC Revision E Release August 2007 -12 Finalize limiting amplifier jitter specifications, combine laser driver and limiting amplifier supply current together in Table 1-3. D Preliminary May 2007 -12 Add TxPwrMon and BIASMON pins to device. Update DC specifications, Functional Description and Applications Information. C Preliminary November 2006 -11 Reflect current device pinout. B Advance August 2006 -11 Update several specifications based on initial device evaluation. A Advance June 2006 NA Initial Release. Description M02096 2.5 Gbps Laser Driver Eye Diagram M02095/6 Pin Configuration 32 31 30 29 28 27 26 25 IREF LOS-ST Config4 Config3 Config2 Config1 RxINm RxINp 1 RxOUTm VCC 3R 24 2 RxOUTp STSET 23 CAPC 22 VCC3T 21 5 TCSLOPE SV CC 20 6 TCSTART OUTN 19 3 VCC R 4 VCC T GND DINp OUTP 18 8 DINm GNDO 17 MODSET BIASMON TxPwrMON APCSET 10 11 12 13 14 Mindspeed Technologies® Mindspeed Proprietary and Confidential 15 IBOUT DIS 9 IPIN FAIL 02095-DSH-001-E 7 16 2 1.0 Product Specification 1.1 Absolute Maximum Ratings These are the absolute maximum ratings at or beyond which the IC can be expected to fail or be damaged. Reliable operation at these extremes for any length of time is not implied. Table 1-1. Absolute Maximum Ratings Symbol Parameter Rating Units VCC Power supply voltage -0.4 to +6.0 V VCC3 3.3V power supply voltage (when VCC3 is connected to VCC) -0.4 to +4.0 V TSTG Storage temperature -65 to +150 °C IBOUT_MAX Maximum bias output current at IBOUT 140 mA IMOD_MAX Maximum modulation current 120 mA 1.2 Table 1-2. Recommended Operating Conditions Recommended Operating Conditions Parameter Rating Units +4.7 to 5.5V or +3.3V ± 7.5% V Junction temperature -40 to +125 °C Operating ambient -40 to +95 °C Power supply: (VCC-GND) (apply no potential to VCC3) or (VCC3-GND) (connect VCC to same potential as VCC3) 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 3 Product Specification 1.3 DC Characteristics 1.3.1 Device Power VCC = 3.05 to 3.55V or 4.7 to 5.5V, TA = -40°C to +95°C, unless otherwise noted. Typical values are VCC = 3.3V, IBOUT = 20 mA, IMOD = 30 mA. Table 1-3. Device Power Symbol Parameter Conditions Minimum Typical Maximum Units – 68 96 mA With PECL Outputs (M02095 - includes PECL load) – 93 108 Additional current when operating from 5V supply (2) – 4 – Using external 3.3V supply VCC = 3.3V (1) With CML Outputs (M02096) ICC VCC (sum of VCCT and VCCR) supply current NOTES: 1. Excludes bias and modulation currents delivered to the laser. Maximum supply current based on maximum settings for bias and modulation. 2. Bias and modulation currents add directly to power supply current in 5V applications; additional supply current noted excludes these currents. 1.3.2 DC Electrical Characteristics - Laser Driver VCC = 3.05 to 3.55V or 4.7 to 5.5V, TA = -40°C to +95°C, unless otherwise noted. Typical values are VCC = 3.3V, IBOUT = 20 mA, IMOD = 30 mA. Table 1-4. DC Electrical Characteristics - Laser Driver Symbol Parameter Conditions Minimum Typical Maximum Units VCC3THL 3.3V supply detection (low voltage) threshold (1) 2.5 2.8 3.05 V VCC3HH 3.3V supply detection (high voltage) threshold (1) 3.65 3.95 4.2 V VCC5THL 5V supply detection (low voltage) threshold 3.9 4.35 4.7 V VCC5THH 5V supply detection (high voltage) threshold 5.5 – – V VMODSET Modulation current ref. Voltage reference for MODSET 1.1 1.25 1.4 V VAPCSET Automatic power control loop voltage reference Voltage at APCSET with APC loop operational 0.90 1.20 1.4 V VFAULTL Low fault voltage detection threshold (IBOUT, OUTP, CAPC, IPIN, MODSET, APCSET) Fault condition occurs when voltage drops below this level – 100 200 mV VFAULTH High fault voltage detection threshold (IPIN) Fault condition occurs when voltage goes above this level (2) VCC3T - 0.2 VCC3T - 0.1 – V VSELFL Self-biased voltage for IBOUT and During disable condition OUTP 0.5 1.65 2.0 V 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 4 Product Specification Table 1-4. DC Electrical Characteristics - Laser Driver Symbol Minimum Typical Maximum Units 1 – 100 mA – – 150 µA – 90 – A/A Ratio of bias current to BIASMON = IBIAS / IBIASMON current 79 89 99 A/A VMD Monitor diode reverse bias voltage 1.5 2 – V IMD Monitor diode current adjustment range For stable APC loop operation in closed loop mode 10 – 1500 µA Ratio of TxPwrMON current to monitor diode current Across range of IMD 0.8 1 1.2 A/A CMDMAX Maximum monitor photodiode capacitance For loop stability; includes any additional parasitic capacitance – – 100 pF VIH_DIS TTL/CMOS input high voltage (DIS) 2.0 – – V VIL_DIS TTL/CMOS input low voltage (DIS) – – 0.8 V VIH_CFG Configuration logic input high voltage (Config1 - 4) (2) VCC3T - 0.5 – – V VIL_CFG Configuration logic input low voltage (Config1 - 4) (2) – – 0.5 V VOH_FAIL Logic output high voltage (FAIL) With external 10 kΩ pull-up to VCC VCC - 0.6 – – V VOL_FAIL Logic output low voltage (FAIL) IOL = 0.8 mA – – 0.4 V Differential input resistance Transmitter Data inputs – 7.5 – kΩ – VCC3T - 1.3 – V VCC3T - 1.5 – VCC3T - VIN(Diff)/4 V 200 – 2400 mV IBIAS IBIAS(OFF) Parameter Bias current adjust range VCMSELF At IBOUT. VIBOUT > 0.7V Bias current with output disabled DIS = high VIBOUT = VCC3 Ratio of bias output current to APCSET current RIN Conditions = IBIAS / IAPCSET in open loop operation Self-biased common mode input Data inputs floating voltage VINCM Common-mode input compliance voltage Transmitter Data inputs VIN(Diff) Differential input voltage = 2*(DINpHIGH – DINpLOW) NOTES: 1. VCC3 supply okay circuitry monitors internally regulated voltage when only the +5V supply is used (VCC = 5V). 2. Input is 3.3V tolerant logic. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 5 Product Specification 1.3.3 DC Electrical Characteristics - Limiting Amplifier VCCR = 3.05 to 3.55V or 4.7 to 5.5V, TA = -40°C to +95°C, unless otherwise noted. Typical values are VCC = 3.3V, 25°C. Table 1-5. DC Electrical Characteristics - Limiting Amplifier Symbol Parameter VAMP_CML CML Output Amplitude Single ended, 50Ω load to VCC; 10 mVPP input (M02096) PECL Output Low Voltage (RxOUTm, RxOUTp) VOUTHPECL(1) PECL Output High Voltage (RxOUTm, RxOUTp) VOUTLPECL(1) VAMP_PECL PECL Output Amplitude RIN_DIFF Differential Input Resistance Conditions Minimum Typical Maximum Units 280 500 – mVPP Single ended; 50Ω load to VCC - 2V (M02095) VCC - 1.88 VCC - 1.71 VCC - 1.60 Single ended; 50Ω load to VCC - 2V (M02095) VCC - 1.09 VCC - 0.95 VCC - 0.88 – 740 – mVPP – 4.5 – kΩ Single ended; 50Ω load to VCC - 2V (M02095) V V ROUT_DIFF Differential Output Resistance CML Outputs (M02096) 170 200 230 Ω VOUTLLOS LOS Output High Voltage Open collector, 4.7 - 10 kΩ pull up to VCC 2.4 – VCC V VOUTHLOS LOS Output Low Voltage IOL = 0.8 mA – – 0.4 V Minimum Typical Maximum Units NOTES: 1. PECL level requirements apply from 0°C to 95°C. 1.4 AC Characteristics 1.4.1 AC Electrical Characteristics - Laser Driver VCCT = 3.05 to 3.55V or 4.7 to 5.5V, TA = -40°C to +95°C, unless otherwise noted. Typical values are VCC = 3.3V, IBOUT = 20 mA, IMOD = 30 mA. Table 1-6. AC Electrical Characteristics - Laser Driver Symbol Parameter IMOD Modulation current adjust range To meet AC specifications (1, 2) 8 – 85 mAPP IMOD(OFF) Modulation current with output disabled DIS = high – – 150 µA Ratio of modulation current to MODMON current (3) – 75 – A/A Ratio of modulation current to MODSET current – 110 – A/A 0 – 104 ppm/°C – 0 (4) - 95 – °C IMOD-TC TTCSTRT Programmable range for modulation current temperature coefficient Conditions Adjustable using TCSLOPE Programmable temperature range at which modulation Based on value set for TCSTART current TC compensation enables 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 6 Product Specification Table 1-6. AC Electrical Characteristics - Laser Driver Symbol tR / tF Parameter Conditions Minimum Typical Maximum Units – – 72 65 95 85 ps Into 25Ω load, off direction – 3 – Into 25Ω load, on direction – 7 – – 1.0 – – 22 40 20% to 80% into 25Ω load. Measured using alternating 1111-0000 pattern at 2.5 Gbps Modulation output rise / fall times M02095; 25Ω load M02096; 25Ω load OS Overshoot of modulation output RJ Random jitter into 25Ω load (includes pulse width distortion) K28.5 pattern at 1.25 Gbps (M02095) DJ Modulation output deterministic jitter % psRMS psPP 23 2 - 1 PRBS at 2.7 Gbps (M02096)) – 15 30 NOTES: 1. Minimum voltage at OUTP > 0.7 V; laser forward voltage and total series resistance must be considered if output is DC coupled to laser. 2. AC specifications apply across this range of mod current. 3. MODMON is accessible using Special Configuration 3 (SC3), see Table 4-3. 4. Default if TCSTART is floating. 1.4.2 AC Electrical Characteristics - Limiting Amplifier VCCR = 3.05 to 3.55V or 4.7 to 5.5V, TA = -40°C to +95°C, unless otherwise noted. Table 1-7. AC Electrical Characteristics - Limiting Amplifier Symbol Parameter VIN(MIN) Minimum Differential Input Sensitivity VI(MAX) Input Overload Conditions Minimum Typical Maximum BER < 10-12 at 2.5 Gbps with 223-1 PRBS (M02096) – 3.3 6 BER < 10-12 at 1.25 Gbps with K28.5 pattern (M02095) – 2 4 1200 – – 600 – – M02096 – – 425 M02095 – – 285 µVRMS BER < 10-12, differential input BER < 10 -12 , single-ended input Units mVPP mVPP VN RMS Input Referred Noise VLOS LOS Programmable Range Differential inputs, 6.04 kΩ ≤ RSTSET ≤ 8.06 kΩ (M02096) 6.04 kΩ ≤ RSTSET ≤ 8.25 kΩ (M02095) – 8 - 60 7 - 60 – mV HYS Signal Detect Hysteresis (electrical); signal detect level set to 20 mVPP 2 4 6 dB 4 – 100 mV Excluding AC coupling capacitors – 4 – kHz Differential, 10 mVPP input, 215-1 PRBS 2.5 Gbps (M02096) – 20 48 ps 1.25 Gbps (M02095) – 20 70 RSSIpp BWLF DJ Peak-to-peak received signal strength indicator range Small-Signal -3dB Low Frequency Cutoff. Deterministic Jitter 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 7 Product Specification Table 1-7. AC Electrical Characteristics - Limiting Amplifier Symbol RJ Parameter Conditions Minimum Typical Maximum Units Random Jitter 10 mVPP input – 3.8 – psRMS tr / tf2.5G Data Output Rise and Fall Times M02096 20% to 80%; outputs terminated into 50Ω; 10 mVPP input – 90 150 ps tr / tf1.25G Data Output Rise and Fall Times M02095 20% to 80%; outputs terminated into 50Ω; 10 mVPP input – 160 250 ps TLOS_ON Time from LOS state until LOS output is asserted LOS assert time after 1 VPP input signal is turned off; signal detect level set to 10 mV 2.3 – 80 µs TLOS_OFF Time from non-LOS state until LOS is deasserted LOS deassert time after input crosses signal detect level; signal detect set to 10 mV with applied input signal of 20 mVPP 2.3 – 80 µs 1.5 Safety Logic Timing VCC = 3.05 to 3.55V or 4.7 to 5.5V, TA = -40°C to +95°C, unless otherwise noted. Typical values are VCC = 3.3V, IBOUT = 20 mA, IMOD = 30 mA. Table 1-8. Safety Logic Timing Symbol Parameter Conditions Minimum Typical Maximum Units t_off DIS assert time Rising edge of DIS to fall of output signal below 10% of nominal (1) – 1 10 µs t_on DIS negate time Falling edge of DIS to rise of output signal above 90% of nominal (1) – 0.4 1 ms t_init Time to initialize Includes reset of FAIL; from power on after Supply_OK or from negation of DIS during reset of FAIL condition – 4 300 ms t_wc Window comparator hold-off time Time during which the status of the fault detect comparators is ignored. 2 3 – ms t_fault Laser fault time -- from fault condition to assertion of FAIL From occurrence of fault condition or when Supply_OK is beyond specified range – 16 100 µs t_reset DIS time to start reset DIS pulse width required to initialize safety circuitry or reset a latched fault – – 10 µs tVCC_OK Supply okay delay time Delay between supply_OK condition and when outputs are enabled – 900 – µs NOTE: 1. With CAPC = 47 nF. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 8 Product Specification Figure 1-1. Safety Logic Simplified Block Diagram DIS SCB Output _Enable Fault_OK Normal Vcc 3_OK Vcc _OK FAIL 3.3V_ONLY ~900 µs typical ~2V TCSLOPE + - SCB Fault_OK S SET Q Normal Activate _Config_Settings R CLR Q ~3 ms typical Configuration settings are not updated while TCSLOPE is pulled high, but are updated when TCSLOPE is at normal level * Fault_OK indicates that no fault is detected at any of the fault sense nodes Table 1-9. Circuit Response to Single-Point Fault Conditions on Driver Pins Pin Name Circuit Response to Over-voltage Condition or Short to VCC Circuit Response to Under-Voltage Condition or Short to Ground Config1-4 Does not affect output power (some conditions can selectively enable/disable driver output). Does not affect output power (some conditions can selectively enable/disable driver output). VCC Outputs are disabled if VCC exceeds the VCC_okay (high level) threshold. If so, FAIL will be asserted. (1) Outputs are disabled if VCC voltage is below the VCC_okay (low level) threshold. If so, FAIL will be asserted. (1) VCC3T Outputs are disabled if VCC3 exceeds the VCC3_okay (high level) threshold. If so, FAIL will be asserted. (1) Outputs are disabled if VCC3 voltage is below the VCC3_okay (low level) threshold. If so, FAIL will be asserted. (1) DINp, DINm The APC loop will attempt to compensate for the change in output power. If the APC loop can not maintain the set average power, a fault state occurs. (2,3) The APC loop will attempt to compensate for the change in output power. If the APC loop can not maintain the set average power, a fault state occurs. (2,3) CAPC A fault state occurs.(2) Laser bias current will be shut off, then a fault state occurs. (2) FAIL Does not affect laser operation. Does not affect laser operation. DIS Bias and modulation outputs are disabled and SVCC is opened. Does not affect laser power (normal condition for circuit operation). MODSET No modulation current. APC loop will adjust output power if DC coupled to laser. A fault state occurs. (2) APCSET Laser output power is reduced (if the modulation outputs DC coupled to laser) or turned off (if the modulation outputs AC coupled to laser). A fault state may occur. (2) A fault state occurs. (2) TCSTART Modulation current may decrease depending on operating Modulation current may increase depending on operating temperature and TCSLOPE setting. APC loop will adjust for change temperature and TCSLOPE setting. APC loop will adjust for in output power if modulation outputs are DC coupled to laser. change in output power if modulation outputs are DC coupled to laser. TCSLOPE Modulation current may increase depending on operating Modulation current may decrease depending on operating temperature and TCSTART setting. APC loop will adjust for change temperature and TCSTART setting. APC loop will adjust for in output power if modulation outputs are DC coupled to laser. change in output power if modulation outputs are DC coupled to laser. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 9 Product Specification Table 1-9. Circuit Response to Single-Point Fault Conditions on Driver Pins Pin Name BIASMON, TxPwrMON Circuit Response to Over-voltage Condition or Short to VCC Circuit Response to Under-Voltage Condition or Short to Ground Does not affect laser operation. Does not affect laser operation. A fault state occurs. (2,4) A fault state occurs. (2,4) IBOUT The laser is turned off and a fault state may occur. (2) A fault state occurs. (2) OUTP Laser modulation is prevented; the APC loop will increase bias current to compensate for the drop in laser power. If the set output power can not be obtained, a fault state occurs. (2,3) A fault state occurs. (2) OUTN Does not affect laser operation. Does not affect laser operation. IPIN GNDO Laser modulation is prevented and a fault state may occur. SVCC Does not affect laser operation. (2) Does not affect laser power. The laser is turned off and a fault state occurs. (2) NOTES: 1. In this case a fault state will assert the FAIL output, but it is not latched. While the fault condition remains, the bias and modulation outputs are disabled and the switch at SVCC is open. No fault occurs if in Safety Circuit Bypass (SCB). 2. In this case a fault state will assert and latch the FAIL output, disable bias and modulation outputs and open the switch at SVCC. No fault occurs if in Safety Circuit Bypass (SCB). 3. Does not affect laser power when the modulation output is AC coupled to the laser. 4. Does not affect laser power in open loop mode or when “Ignore IPIN” is selected. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 10 Product Specification Figure 1-2. M02095/6 Safety Logic Timing Characteristics SLOW RAMPING 3.3V Operation (DIS Low) HOT PLUG (DIS Low) 3.3V “OK” Supply VCC (1) 3.3V FAIL VCC3 t_init < 5 ms (3 ms typ.) Low DIS DIS Low t_init < 5 ms (3 ms typ.) Low FAIL Low Laser Output Laser Output SLOW RAMPING 5V Operation (DIS Low) TRANSMITTER ENABLE 5V “OK” VCC Supply (1) 3.3V t_on < 1 ms (300 µs typ.) VCC3 FAIL FAIL DIS Low t_init < 5 ms (3 ms typ.) Low High DIS Low Low Laser Output Laser Output TRANSMITTER DISABLE “OK” Supply Fault sense node such (2) as IB OUT (1) FAIL Low RESPONSE TO FAULT Fault Occurs Normal t_off < 10 µs (1 µs typ.) Low High FAIL Low t_fault < 100 µs (4 µs typ.) High DIS DIS Low Low Laser Output Laser Output 1. Supply “OK” means both VCC and VCC3 are within their defined operating windows. 2. A fault occurs when IPIN goes high or low; a fault at IPIN does not apply when “Ignore IPIN” configuration is selected. NOTE: “Laser Output” is equivalent to bias current plus modulation current. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 11 Product Specification Figure 1-3. M02095/6 Safety Logic Timing Characteristics (Continued) FAULT RESET ATTEMPT FAULT RECOVERY BEHAVIOR Fault sense node such (2) as IB OUT Low Normal Fault Removed Fault sense node such (2) as IB OUT Low High FAIL FAIL Low DIS t_reset 10 µs DIS Laser Output t_on < 1 ms (300 µs typ.) Laser Output 10 - 20 µs 10 µs (Does not turn on) FAULT RESET ATTEMPT Fault sense node such (2) as IB OUT FAIL Low t_init < 5 ms (3 ms typ.) DIS Laser Output 10 µs 1. Supply “OK” means both VCC and VCC3 are within their defined operating windows. 2. A fault occurs when IPIN goes high or low; a fault at IPIN does not apply when “Ignore IPIN” configuration is selected. NOTE: “Laser Output” is equivalent to bias current plus modulation current. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 12 2.0 Pin Definitions Table 2-1. M02095/6 Pin Descriptions (1 of 2) QFN Pin Number Pin Name Function 1 RxOUTm Limiting amplifier inverting data output (M02095 - PECL, M02096 - CML). Either output type is referenced to the Rx supply input (VCCR). 2 RxOUTp Limiting amplifier non-inverting data output (M02095 - PECL, M02096 - CML). Either output type is referenced to the Rx supply input (VCCR). 3 VCCR Power supply input for limiting amplifier circuitry (3.3V or 5V). 4 VCCT Power supply input for laser driver circuitry (3.3V or 5V). 5 TCSLOPE Modulation temperature compensation slope. A resistor to ground sets the level of temperature compensation for the modulation current. Forcing this pin high (to 3.3V) causes the configuration logic to ignore configuration logic settings until this pin is released to its normal level (~1.25V). Temperature compensation is disabled if this pin is floating. 6 TCSTART A resistor to ground at this pin sets the temperature at which the modulation temperature compensation slope becomes active. Letting this pin float results in a start temperature of ~0°C. Grounding this pin disables temperature compensation. 7 DINp Transmitter positive Data Input. Internally terminated with 4 kΩ to self-bias voltage of approximately VCC3T - 0.65V. Can be AC coupled. 8 DINm Transmitter negative Data Input. Internally terminated with 4 kΩ to self-bias voltage of approximately VCC3T - 0.65V. Can be AC coupled. 9 FAIL Safety circuit fault indicator. Goes high when a safety logic fault is detected. The FAIL output is low when DIS is high. Open collector; 4.7 kΩ to 10 kΩ external pull-up required. 5V compatible when using a 5V supply. 10 DIS Disable control (TTL compatible). When high or left floating, the bias and modulation outputs are disabled. Set low for normal operation. 7 kΩ internal pull-up to VCCT. 11 MODSET Modulation Current Adjust. Connect a resistor between this pin and ground to set laser modulation current. 12 BIASMON Bias output current monitor. Terminate with a resistor to ground to set the desired full-scale voltage at maximum bias current. Some internal functions can be muxed to this pin via the configuration logic. See configuration logic table for more detail. 13 TxPwrMON Transmit power monitor. Provides a 1:1 mirror of the monitor photodiode current. Terminate with a resistor to ground to set the desired full-scale voltage at maximum photodiode current. 14 APCSET 15 IPIN 16 IBOUT Laser bias current output. Connect to laser cathode through a ferrite. 17 GNDO Ground for modulation output stage. Connect directly to ground or can connect to ground through an inductor. 02095-DSH-001-E A resistor connected from this pin to ground sets laser output power. Monitor photodiode input. Connect this input to the monitor photodiode anode for automatic power control. The monitor photodiode cathode should be connected to SVCC or VCC3T. Mindspeed Technologies® Mindspeed Proprietary and Confidential 13 Pin Definitions Table 2-1. M02095/6 Pin Descriptions (2 of 2) QFN Pin Number Pin Name 18 OUTP Transmitter positive modulation output. Draws current when DINp is high. Referenced to the SVCC (transmitter regulator output) voltage. 19 OUTN Transmitter negative modulation output. Draws current when DINp is low. Referenced to the SVCC (transmitter regulator output) voltage. 20 SVCC Internal power supply switch for laser. Provides redundant shutdown during a disable or fault condition. 21 VCC3T Internally regulated voltage for laser driver circuitry in 5V applications. Connect directly to supply to allow wider power supply tolerance in 3.3V-only applications (internal regulator not in use). Do not connect to power supply if VCC = 5V. 22 CAPC A capacitor at this pin sets the dominant pole for automatic power control. Connect a capacitor between this pin and VCC3 if automatic power control is used. Can leave floating if using open loop configuration. 23 STSET Loss of signal threshold setting input. Connect a resistor between this pin and VCC3R to set loss of signal or signal detect threshold. 24 VCC3R Internally regulated voltage for limiting amplifier circuitry in 5V applications. Connect directly to supply to allow wider power supply tolerance in 3.3V-only applications (internal regulator not in use). Do not connect to power supply if VCC = 5V. 25 RxINp Non-inverting limiting amplifier data input. Internally terminated with 2 kΩ to self-bias voltage of approximately VCC3R - 0.5V. 26 RxINm Inverting limiting amplifier data input. Internally terminated with 2 kΩ to self-bias voltage of approximately VCC3R - 0.5V. 27 Config1 28 Config2 29 Config3 30 Config4 31 LOS-ST 32 IREF 02095-DSH-001-E Function Configuration logic input. These pins select laser driver and limiting amplifier configurations and test modes. Refer to Configuration Logic table (Table 4-3) for more information. Three level logic where nominal level is midrange (VCC3T / 2) when floating. Limiting amplifier LOS or ST (signal detect) output. Configuration logic selects whether output is to be LOS or ST. 5V compatible when using a 5V supply. Internal reference current. Must be connected to ground through a 12.4 kΩ 1% resistor. Mindspeed Technologies® Mindspeed Proprietary and Confidential 14 Pin Definitions Figure 2-1. M02095/6 Package Pin-out (5x5mm MLF) 32 31 30 29 28 27 26 25 IREF LOS-ST Config4 Config3 Config2 Config1 RxINm RxINp 1 RxOUTm VCC 3R 24 2 RxOUTp STSET 23 3 VCC R CAPC 22 4 VCC T VCC3T 21 5 TCSLOPE SV CC 20 6 TCSTART OUTN 19 GND 7 DINp OUTP 18 8 DINm GNDO 17 MODSET BIASMON TxPwr MON APCSET 11 12 13 14 Mindspeed Technologies® Mindspeed Proprietary and Confidential 15 IBOUT DIS 10 IPIN FAIL 02095-DSH-001-E 9 16 15 3.0 Functional Description 3.1 Overview The M02095/6 devices are a highly integrated combined laser driver and limiting amplifier intended for applications to 2.5 Gbps, depending on device type. The parts can be operated from a single 3.3V or 5V supply. Many features are user-adjustable, including the APC loop bias control (via a monitor photodiode), modulation current, temperature compensation control of modulation current, loss of signal threshold, using jam or not on the Rx path and the Rx and Tx polarity. Safety circuitry is also included to provide a latched shut-down of laser bias and modulation current if a fault condition occurs. An internal VCC switch provides redundant shutdown of the laser current under a fault condition. Figure 3-1. M02095/6 Block Diagram VCC3R VCC R STSET Threshold Setting Circuit Regulator RxOUTp Output Buffer RxOUTm 2kΩ Limiting Amplifier RxINp Vttr 2kΩ RxINm Rx_Polarity LOS-ST Offset Cancel LOS Level Detect Comparator DCR_Disable VCCT To Safety Logic 3.3V Regulator with Bypass TCSTART VCC3T To Safety Logic Modulation Control TCSLOPE Iref RSSI LOS-ST_sel LOS-to-JAM Biasing SVCC MODSET DIN- 4kΩ Output Buffer Input Buffer Tx_Polarity Rx_Polarity Tx_Polarity CONFIG_3 V CC VCC3 CONFIG_4 LOS-ST_sel IBOUT SCB LOS-to-JAM Safety Circuitry with Latched Fault TX Disable GND Laser Power Control IPIN FAIL RESET DIS 02095-DSH-001-E Analog MUX TxPwrMon DCR_Disable APCSET Configuration Logic GND0 BIAS_Mon CAPC CONFIG_1 CONFIG_2 OUTOUT+ Laser Driver Mindspeed Technologies® Mindspeed Proprietary and Confidential BIASMON 4kΩ Vttx TxPwr MON DIN + 16 Functional Description 3.2 General Description The M02095 and M02096 integrate a laser driver and limiting amplifier in one highly configurable device for applications to 1.25 Gbps and 2.5 Gbps respectively. The Tx and Rx paths are independently operated and configurable using four three state configuration inputs allowing more than 80 user variations. The laser driver supplies the bias and modulation current required to drive an edge emitting laser and incorporates automatic power control, a power supply switch for redundant shutdown during a fault, user settable temperature compensation of modulation current and SFP compliant safety circuitry. The limiting amplifier includes user settable input signal level detection circuit and a fully integrated DC-offset cancellation loop that does not require any external components. Using the configuration logic, the limiting amplifier output can be jammed when loss of signal occurs and polarity control is available for both the driver and limiting amplifier data paths. Finally, using an internal self selecting regulator, the devices can operate from either a 3.3V or 5V supply with no changes to its configuration. 3.2.1 Internal Regulator The M02095/96 contain an internal 3.3V regulator so high bit rate performance can be achieved with either a 5V or 3.3V power supply. When operating from a 5V supply (VCC connected to +5V), an internal regulator provides a voltage of approximately 3.3V to the majority of the on-chip circuitry. The on-chip regulator is internally compensated, requiring no external components. When a 3.3V supply is used (VCC connected to 3.3V, or both VCC and VCC3 connected to 3.3V), internal logic configures the device for 3.3V operation and the regulator is switched to a lowresistance mode. The device decides whether or not the internal regulator is enabled using internal sensing logic, the sensing logic also determines whether the device safety circuitry needs to monitor for proper +5V supply voltage. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 17 Functional Description 3.2.2 Configuration Logic The four configuration pins allow the user to select over 80 configurations for the M02095/96. Each input has three states: tied high, tied low or floating. When floating, the respective configuration pin internally is brought to ~VCC3T/2 and this is decoded separately from either a high or low state. See Figure 3-2. Table 3-1. M02095/6 Configuration Logic Selections Function Function DIS/EN: The laser driver DIS pin is either active high “Tx_Disable” or active high “Tx_Enable”. Note that the DIS pin has an active high pull-up regardless of its function. SCB Safety Circuit Bypass. If SCB is selected, a Tx Fault condition will not be latched and the safety circuitry will not disable the bias and modulation outputs. Fail will be asserted only while the fault is present. LOS/ST Defines the limiting amplifier LOS-ST pin as either ST (goes high with signal detect) or LOS (goes high with LOS). LOS=JAM / NO_JAM When “LOS=Jam” the limiting amplifier outputs are jammed when a loss of signal occurs. This is separate from whether the LOS/ST pin is defined to be either LOS or ST. TxPOL Defines the relationship between DIN+ and OUT+ in the Tx path. RxPOL Defines the relationship between RxINp and RxOUTp in the Rx path. Special Config Figure 3-2. Enables multiple specific configurations modes for the user. See Table 4-4 in Section 4.4 of this datasheet. Configuration Pin Input VCC VCC3T ~60 kΩ CONFIG_X 180 Ω ~60 kΩ 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 18 Functional Description 3.3 Laser Driver Description 3.3.1 Driver Inputs Inputs to the laser driver data buffer are self-biased through 4 kΩ resistors to an internal reference of approximately VCC3T - 1.3V (Figure 3-3). (VCC3T is the internally regulated voltage for laser driver circuitry in 5V applications or is the bypassed regulator output in 3.3V applications). Both CML and PECL input signals can be AC coupled to the M02095/6. In most applications the data inputs are AC coupled with controlled impedance pcb traces which will need to be terminated externally with a 100Ω resistor between the DIN+ and DIN- inputs. AC coupling is recommended when using the internal regulator (VCC = 5V), though external level-shifting may be used if DC coupling is desired with a 5V supply. It is possible to invert the polarity of the driver inputs using the configuration logic (Table 4-3). Figure 3-3. Laser Driver Data Inputs Figure 3-4. Modulator Outputs 0.75 nH * VCC 80fF VCC3T - 1.3V 0.75 nH OUTN * OUTP 3.75 kΩ DIN * Denotes bond wire internal inductance to MLF package GNDO (optional external inductance) 3.3.2 Driver Output Stage The laser driver output stage (Figure 3-4) incorporates feedback to maintain performance over the range of laser modulation current. The output stage is nominally configured to drive an approximate 25Ω output load. When DC coupled, OUTP should be connected through a series resistor to the laser such that the total impedance seen at the output is approximately 25Ω. This will result in the optimum pulse response while allowing the maximum modulation current to be achieved. The output can also be AC coupled to the laser. When AC coupled the dynamic resistance seen by OUTP should still be 25Ω. In addition to a resistor in series with the laser, a capacitor is added in series and a ferrite is used to pull up the collector at OUTP to VCC. When the laser is AC coupled, the OUTN pin is usually tied to the laser anode through an AC coupled series resistor which matches the impedance seen by the OUTP pad. Laser modulation current is controlled by adjusting current at MODSET (Figure 3-5). 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 19 Functional Description The output stage also has a separate current path to GND labelled GNDO. This isolates the output switching currents from the rest of the device. 3.3.3 Modulation Control The modulation current amplitude is controlled by the MODSET input pin. The modulation current can be temperature compensated by setting slope through the TCSLOPE pin and TCSTART (Figure 3-6) sets the temperature at which the temperature compensation begins to operate. The temperature compensation is independent of the modulation current setting. APCSET, MODSET and TCSLOPE Input Figure 3-5. VCC TCSLOPE TCSTART Input VCC VCC3T MODSET , APCSET, or Figure 3-6. + - 1.28V TCSTART 4.2 kΩ 190 Ω 3.2 kΩ 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 20 Functional Description 3.3.4 Bias Current Generator (Figure 3-7) and Automatic Power Control The M02095/6 include circuitry to automatically maintain laser average output power with use of a monitor photodiode. The monitor photodiode cathode is connected to VCC3 (or SVCC) and the anode is connected to IPIN (Figure 3-8). A feedback loop maintains the monitor photodiode current set by the current at APCSET (Figure 3-5). The monitor diode photo current is mirrored and an equivalent current is sourced from TxPwrMON (Figure 3-9). Figure 3-7. IBIASOUT Figure 3-8. VCC VCC3T IPIN Input VCC 14 kΩ IBIAS OUT IPIN 26 kΩ 30 Ω 14 kΩ A capacitor between CAPC (Figure 3-10) and VCC3 sets the dominant pole for APC loop stability. The bias generator also includes a bias current monitor (BIASMON, Figure 3-9), whose output current is typically 1/90th of the bias current. Figure 3-9. TxPwrMON and BIASMON Outputs VCC Figure 3-10. CAPC Input VCC3T VCC 30 Ω CAPC TxPwrMON or BIASMON 190 Ω 190 Ω 190 Ω 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 21 Functional Description 3.3.5 Fail Output The M02095/96 has an open collector FAIL alarm output (Figure 3-11) which is compatible with the TX_FAULT signalling requirements of common plugable module standards. The Fail output is 5V compatible whether the M02095/96 is using a 5V or 3.3V supply. It requires an external 4.7kΩ to 10 kΩ pull-up resistor so if the M02095/96 loses power the pull-up will signal a fail condition. In a simple static protection scheme used by other ICs the protection diodes would clamp the FAIL signal to ground when the chip loses power. 3.3.6 Tx Disable Control The DIS (Figure 3-12) pin is used to disable the transmit signal (both the modulation and bias current are disabled when DIS = high or is floating). Depending on the configuration logic settings (Table 4-3), the DIS pin can redefined as an enable (EN) pin. In this case, both the modulation and bias current are enabled when EN = high or is floating). The DIS input is compatible with TTL levels regardless of whether VCC = 5V or VCC = 3.3V. The external 4.7 kΩ to 10 kΩ pull-up resistor required by most interface standards is not needed because this pin has an internal 7 kΩ resistor to VCC. Figure 3-11. FAIL Output Figure 3-12. DIS (or EN) Input VCC FAIL VCC3T 7 kΩ DIS 80 k Ω 3.3.7 Safety Circuitry Comparators at APCSET, MODSET, IBOUT, IPIN, OUTP, and CAPC will assert the FAIL (Figure 3-12) output, indicating that a fault condition has occurred (see Table 1-9). This condition is latched and requires DIS (Figure 3-11) to be toggled or power cycling before reset occurs. SVCC is opened during a fault or disable condition. By setting DIS high, the bias and modulation output currents are disabled. DIS will disable laser bias and modulation current if left floating. DIS must be forced to a low state to enable the outputs. When safety circuit bypass (SCB) mode is enabled, FAIL will indicate a fault condition but is not latched and the outputs will not be disabled. Only the DIS pin will shutdown the outputs when in SCB mode. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 22 Functional Description 3.3.8 Current Monitors Output monitors are provided for transmit power (TxPwrMON) bias (BIASMON) and modulation current (MODMON). MODMON has limited availability through a configuration logic setting (Table 4-3) for the M02095/6. These monitors source current and should either feed into a current-input ADC or terminated with a resistor to ground that sets the desired full-scale voltage. Figure 3-13. MODMON Output VCC VCC3T MODMON 190 Ω 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 23 Functional Description 3.4 Limit Amp Description 3.4.1 Inputs The data inputs are internally connected to VTTR via 2 kΩ resistors and generally need to be AC coupled. Referring to Figure 3-14, the nominal VTTR voltage is 2.85V because of the internal resistor divider to VCC3R, which means this is the DC potential on the data inputs. See the applications information section for further details on choosing the AC-coupling capacitor. It is possible to invert the polarity of the limit amp inputs using the configuration logic (Table 4-3). Figure 3-14. CML Data Inputs VCC VCC3R VCC3R – 0.45V 2.25kΩ 2.25kΩ RxINp 3.4.2 1.4kΩ 8.8kΩ RxINm DC Offset Compensation The M02095/96 contains an internal DC autozero circuit that can remove the effect of DC offsets without using external components. This circuit is configured such that the feedback is effective only at frequencies well below the lowest frequency of interest. The low frequency cut off is typically 4 kHz. It is possible to reduce the DC servo cutoff frequency using an external capacitor or to disable the servo loop completely using the configuration logic (Table 4-3). This is described in more detail in the applications section. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 24 Functional Description 3.4.3 CML Outputs The M02096 CML output configuration is shown in Figure 3-15. The outputs are internally terminated to VCC3R through a 100Ω resistor and have a nominal amplitude of 260 mVPP. Figure 3-15. CML Data Outputs (M02096) VCC VCC VCC3R 100 Ω Figure 3-16. PECL Data Outputs (M02095) VCC3R 100 Ω RxOUTp RxOUTp RxOUTm RxOUTm ITAIL 3.4.4 PECL Outputs The M02095 features 100k/300k PECL swing compatible outputs as shown in Figure 3-16 that are referenced to VCC3R. The outputs may be terminated using any standard AC or DC-coupling PECL termination technique. ACcoupling is used in applications where the average DC content of the data is zero e.g. SONET. The advantage of this approach is lower power consumption, no susceptibility to DC drive and compatibility with non-PECL interfaces. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 25 Functional Description 3.4.5 Loss of Signal/Signal Detect (LOS-ST) The M02095/96 features input signal level detection over an extended range. Using an external resistor between pin STSET (Figure 3-18) and VCC3R the user can program the input signal threshold. This function can be programmed using the configuration logic (Table 4-3) to either represent signal detect (ST) or loss of signal (LOS). For a given RST resistor setting, the difference between the ST and LOS threshold is a fixed hysteresis. The signal detect status is indicated on the LOS-ST output pin shown in Figure 3-17. LOS is active when the signal is below the threshold value, ST is active when the signal is above the threshold value. The signal detection circuitry has the equivalent of 4 dB electrical hysteresis. Figure 3-17. LOS-ST Output Figure 3-18. STSet Input VCC 80 k Ω VCC3R LOS-ST VCC RST VSTSET STSET 3.4.6 JAM Function (“Squelch”) (Special Configuration Mode) When enabled through the configuration logic (Table 4-3), when LOS is asserted (ST is deasserted) an internal connection between LOS and the output buffer forces the data outputs to a logic “one” state. This ensures that no data is propagated through the system. The loss of signal detection circuit can be used to automatically force the data outputs to a high state when the input signal falls below the LOS threshold. The function is normally used to allow data to propagate only when the signal is above the user's bit-error-rate requirement. It therefore inhibits the data outputs toggling due to noise when there is no signal present. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 26 Functional Description 3.4.7 Peak to Peak Received Signal Strength Indicator (RSSIPP) (Special Configuration Mode) When enabled through the configuration logic (Table 4-3), the RSSIPP output voltage is made available on the TxPwrMON output pin. the RSSI voltage is logarithmically proportional to the peak to peak level of the input signal. It is not necessary to connect an external capacitor to this output. Figure 3-19. RSSIPP Output (when configured by the Configuration Logic) VCC3R VCC RSSI PP 4 kΩ I(RSSI PP) 3.4.8 Reference Current Generation The M095/96 contains an accurate on-chip bias circuit that requires an external 12.4 kΩ 1% resistor, RREF, from pin IREF to ground to set the LOS-ST threshold voltage at STSET precisely. Figure 3-20. Reference Current Generation VCC3R RST STSET VSET LOS VDet BG_Ref I REF RREF 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 27 4.0 Applications Information 4.1 General • 2.5 Gbps STM-16/OC-48 SDH/SONET (M02096) • 1.06 and 2.12 Gbps Fibre Channel (M02095/6) • 1.25 Gbps Ethernet (M02095/6) • 1.25 Gbps SDH/SONET (M02095/6) • 2.67 Gbps SDH/SONET with FEC (M02096) • SDH/SONET 155 Mbps Transceivers • FTTx and Media Converters Figure 4-1. Application Diagram, Laser AC Coupled Example VCC VCC3R VCCR STSET RxOUTp Clock Data Recovery Unit V CC3R Threshold Setting Circuit Regulator AC-Coupled RxINp to TIA Output Buffer RxOUTm 2kΩ Limiting Amplifier Vttr 2kΩ RxINm M0201x Photodiode Rx_Polarity LOS-ST AC or DC Coupled (as described in Applications Information) Offset Cancel LOS Level Detect Comparator VCC DCR_Disable VCC T To Safety Logic 3.3V Regulator with Bypass TCSTART To Safety Logic Modulation Control TCSLOPE Iref RSSI LOS-ST_sel LOS-to-JAM Biasing VCC3T SVCC MODSET OUT- DIN + DeMux Output 4kΩ DIN - Vttx 4kΩ Rx_Polarity Tx_Polarity CONFIG_2 CONFIG_3 Configuration Logic LOS-ST_sel OUT+ GND0 BIAS_Mon Analog MUX VCC VCC3 TxPwrMon DCR_Disable LOS-to-JAM CONFIG_4 GND Laser Driver Tx_Polarity CONFIG_1 Configuration Control (V CC, GND or Float) Output Buffer Input Buffer IBOUT SCB Safety Circuitry with Latched Fault TX Disable Laser Power Control IPIN BIASMON TxPwrMON APCSET CAPC FAIL DIS RESET VCC 3T 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 28 Applications Information 4.2 Laser Driver Connections 4.2.1 Configuring the Laser Driver Output The laser driver output configuration needs to be optimized for the device type and configuration. Figure 4-2 shows a typical schematic of the laser driver connections for both AC and DC coupling. Table 4-1 provides the recommended starting component values for the two configurations. Figure 4-2. Laser Driver Output and Typical Component Values RXINP RXINM 26 25 3.3V2_T DNI R88 0 DNI L1 10UH SVCC_B OUTN_B OUTP_B FB1 1 KPD/ALD 100MA DNI FB3 100MA FB7 0 15IPIN 16IBOUT DNI L2 10UH TOSA R92 68 DNI FB4 100MA 2 KLD C45 2.7PF R90 2 APD 24 VCC3R 23 STSET 22 CAPC 21 VCC3T 20 SVCC 19 OUTN 18 OUTP 17 GND0 3 LD1 DNI R87 24.9 0 R89 R91 0 20 FB2 IBOUT_B 100MA IPIN_B FB8 2 1 3 100MA JP2 Table 4-1. DNI C46 0.001UF 2 Suggested Starting Component Values for Laser Driver Connections Component AC Coupled Laser DC Coupled Laser R88 0Ω open L1, 2 10 µH FB3, 4 FB1, 2, 8 open Ferrite (1) open Ferrite (1) Ferrite (1) R89, 90 100 nF 0Ω R92 (2) 68Ω 68Ω C45 (2) 2.7 pF 2.7 pF R87 25Ω 25Ω R91 20Ω 20Ω 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 29 Applications Information Table 4-1. Suggested Starting Component Values for Laser Driver Connections Component AC Coupled Laser DC Coupled Laser C46 open open FB7 0Ω 0Ω NOTES: 1. Ferrite bead, 600Ω, 100 MHz, 100 mA typical. Similar to Murata BLM18HD601SN1. 2. C45 and R92 are compensation components for the laser TO can inductance. Actual values are determined by experimentation but typically fall within 0 to 30 pF and 0 to 200Ω. 4.2.2 Modulation Control There are programmable control lines for controlling the modulation current and its temperature compensation. These inputs can be programmed simply with a resistor to ground. The modulation current amplitude is controlled by the MODSET input pin. The modulation current is temperature compensated by the TCSLOPE inputs. The temperature compensation is independent of the setting. If the temperature compensation at TCSLOPE is disabled, the modulation output current is: IMOD = 110 x (1.25V / RMODSET) Where RMODSET is the resistance from pin MODSET to ground. 4.2.2.1 Setting Modulation Temperature Compensation Temperature compensation involves setting two parameters: the temperature at which the compensation starts TCSTART (°C) and the slope TCSLOPE (% compensation / °C). Figure 4-3 graphically illustrates the selection of the resistor at the TCSTART pin (RTCSTART). For example, to have the temperature compensation start at 30°C, chose RTCSTART = 15 kΩ. With TCSTART floating, the start temperature defaults to ~0°C. The percent change per degree C is set by the selection of RTCSLOPE at the TCSLOPE pin. The range varies from 0 to one percent of modulation current change per degree C. Note that the starting modulation current is the that set by RMODSET when the temperature is below that of RTCSTART. Figure 4-4 illustrates the behavior of the output modulation current as the temperature increases for a range of resistors at the TCSLOPE pin. This is the most accurate method for selecting RTCSLOPE. However, you can also select RTCSLOPE using the following relationship: RTCSLOPE = 19.5*(TC)-1.5, where TC is the desired slope of the modulation current from 25°C to 85°C in “%/°C” and RTCSLOPE is in kΩ. If no temperature compensation is desired, leave RTCSLOPE open. In any case, RTCSLOPE will have negligible effect at M02095/6 ambient temperatures below the TCSTART temperature. For example: Given a laser with a desired modulation current at low temperatures of 30mA and a temperature coefficient of 0.5%/°C at high temperatures (which will require a laser driver temperature coefficient of +0.5%). Choose RMODSET = 110 x (1.25V / 30mA) = 4.6 kΩ Choose RTCSLOPE =19.5*(0.5)-1.5 kΩ = 55 kΩ. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 30 Applications Information Figure 4-3. Selecting RTCSTART for a Given Start Temperature Temperature Compensation Start Temperature on the M02095/96 65 60 55 Rstart Value (k Ω ) 50 45 40 35 30 25 20 15 10 5 0 0 10 20 30 40 50 60 70 80 90 Desired Temperature Compensation Start Temperature (°C) Effect of RTCSLOPE on IMOD vs. Temperature for RTCSTART = 25°C (25kΩ) Figure 4-4. M02095/M02096 Rslope Characteristics with Temperature Percent Change in Modulation Current Relative to Programmed Start Temperature 100 90 80 24kΩ 30kΩ 39kΩ 51kΩ 62kΩ 91kΩ 150kΩ 300kΩ 70 60 50 40 30 20 10 0 -10 -20 -40 -30 -20 -10 0 10 20 30 40 50 60 70 80 90 Ambient Temperature (°C) 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 31 Applications Information 4.2.3 Setting Automatic Power Control To maintain laser average output power the laser monitor photodiode cathode is connected to VCC3 (or SVCC) and the anode is connected to IPIN. The current from the monitor photo diode mounted in the laser package is sunk at IPIN. The APC loop adjusts the laser bias current so that the current into IPIN from the monitor photo diode equals the current set at APCSET by the user selection of RAPCSET. RAPCSET = 1.25 V / IPIN An internal feedback loop maintains the monitor photodiode current set by the current at APCSET. The resulting laser bias current is determined by the value of the external resistor RAPCSET (the external resistor connected between the APCSET pin and ground) and the transfer efficiency between the laser and monitor photo diode. The monitor diode photo current is mirrored and an equivalent current is sourced from TxPwrMON. TxPwrMON can be connected directly to a current input ADC or through a resistor to ground. If this function is not needed this pin can be left open. A capacitor between CAPC and VCC3 sets the dominant pole for APC loop stability. The APC loop includes circuitry allow for good t_on times, even with higher CAPC values. For example, a 47 nF capacitor can be used at CAPC, providing a low-frequency cutoff typically around 1 kHz while still achieving a t_on < 1 ms. This makes it easy to use the M02095/6 in low rate or multi-rate applications. The bias current monitor (BIASMON) output current is typically 1/90th of the bias current. This pin can be connected directly to a current input ADC or through a resistor to ground. If this function is not needed this pin can be left open. Open loop operation can also be achieved by connecting BIASMON to IPIN. The open loop bias current is set by adjusting RAPCSET. TxPwrMON effectively acts like a bias monitor (duplicate of BIASMON) in this configuration. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 32 Applications Information 4.3 Limiting Amplifier Connections 4.3.1 Reference Current Generation The M02095/96 contain an accurate on-chip bias circuit that requires an external 12.4 kΩ 1% resistor, RREF, from pin IREF to ground to set the LOS threshold voltage at STSET precisely. Figure 4-5. Reference Current Generation VCC R ST STSET VSET LOS VPP_LVL_Det BG_Ref IREF R REF 4.3.2 12.4 kΩ Input Matching and Choosing an Input AC-Coupling Capacitor Depending on the intended data rate or data rates, the use of an 100Ω resistor in shunt across the limiting amplifier inputs may be used to achieve good high frequency matching between the TIA output and the limiting amplifier input. For applications above 1 Gbps, it is recommended that this resistor be used. The minimum value of AC coupling between the TIA and limit amp depends on whether the limit amp input has this external shunt matching resistance. When AC-coupling the input the coupling capacitor should be of sufficient value to pass the lowest frequencies of interest, bearing in mind the number of consecutive identical bits, and the input resistance of the part. For SONET data, a good rule of thumb is to chose a coupling capacitor that has a cut-off frequency less than 1/(10,000) of the input data rate. For Ethernet or Fibre Channel, there are less consecutive bits in the data, and the recommended cut-off frequency is 1/(1,000) of the input data rate. In all cases, a high quality coupling capacitor should be used as to pass undistorted the high frequency content of the input data stream. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 33 Applications Information 4.3.2.1 Data Rates Greater than 1 Gbps In this case a 100Ω resistor should be connected between RxINp and RxINm close to the limiting amplifier inputs to achieve good match with properly designed 50Ω Zo transmission lines to the input. The value for the AC coupling capacitor then depends on the actual datarate and whether the data is SONET or Ethernet/Fibre Channel based. For example, for 2.5 Gbps SONET data, the coupling capacitor should be chosen as: fCUTOFF ≤ (2.5x109 / 10x103) = 250x103 The -3 dB cutoff frequency of the low pass filter at the input is found as (assuming the TIA output is 50Ω single ended): f3dB = 1/ (2 π * 100Ω * CAC) so solving for C where f3dB = fCUTOFF CAC = 1/ (2 π * 100Ω * fCUTOFF) EQ.1 and in this case the minimum capacitor is 6.4 nF. For 1.25 Gbps SONET data, the minimum capacitor is twice this or 12.8 nF. In all cases, a capacitor larger than calculated above results in a lower cutoff frequency due to the ac coupling between the TIA and the limiting amplifier inputs. 4.3.2.2 Applications below 1 Gbps The M02095/96 limiting amplifier is ideally suited for low data rate operation because of its low DC servo cutoff frequency and high input resistance. The low servo cutoff frequency improves low data rate performance in the same way that having the AC coupling capacitor sized appropriately for the data rate and longest consecutive string of ones or zeros. The high input resistance means that the AC coupling capacitor need not be nearly as large as in the case of a device with a 50Ω input resistance. For 155 Mbps SONET data, the input coupling capacitor needs to be large enough to pass 15 kHz (155x106/10,000) resulting in a minimum capacitor value of 5 nF and for 100 Mbps ethernet, the minimum capacitor is even smaller. In either case, a simple choice is the widely available 10 nF capacitor. 4.3.3 Setting the Signal Detect Level Based on the configuration logic setting (see Table 4-3), the LOS-ST output is either configured to either go high with signal detect (ST output) or to go high with the loss of signal (LOS). Figure 4-6 shows the relationship of the LOS-ST output when defined as LOS across the range of RST resistors. When configured as an ST output, the labels “Assert” and “Deassert” are interchanged. Table 4-2 lists the Assert and Deassert values for 1% resistors. As shown in Figure 4-1, RST is connected between STSET and VCC3R. To minimize LOS-ST variation, it is recommended that a 1% resistor be used for RST. And as shown in Figure 4-5, the tolerance of the 12.4 kΩ resistor at IREF also affects the LOS-ST accuracy. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 34 Applications Information Table 4-2. Typical LOS Assert and De-assert Levels for Various 1% RST Resistor Values VIN (mVPP) differential RST (kΩ) VIN (mVPP) differential LOS Assert/ST DeAssert LOS De-Assert/ST Assert RST (kΩ) 6.04 62.0 93.0 6.19 52.6 6.34 LOS Assert/ST DeAssert LOS De-Assert/ST Assert 7.15 20.0 30.2 79.1 7.32 17.4 26.2 44.6 68.1 7.50 14.4 22.4 6.49 37.3 58.8 7.68 11.9 19.3 6.65 31.6 49.6 7.87 10.0 16.2 6.81 27.2 42.0 8.06 8.2 13.6 6.9 11.3 6.98 23.6 35.6 8.25 (1) NOTE: 1. M02095 Only. Figure 4-6. Typical Loss of Signal Characteristic vs. RST (use 1% Resistor tolerance) Threshold Level (mV PP) Typical Loss of Signal Characteristic 120 100 80 60 DeAssert 40 20 0 6.00 Assert 6.50 7.00 RST (kΩ ) 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 7.50 8.00 M02096 maximum 35 Applications Information 4.3.4 Using JAM As shown in Figure 4-1, there is an optional internal connection between LOS and Jam. If this connection is enabled via the configuration logic (), when LOS asserts the Jam function sets the data outputs to a fixed “one” state (RxOUTp is held high and RxOUTm is held low). This is normally used to allow data to propagate only when the signal is above the users' bit error rate (BER) requirement. It prevents the outputs from toggling due to noise when no signal is present. The internal connection between LOS and Jam is independent of whether the LOS-ST output is configured as a LOS output or an ST output. 4.3.5 PECL Output Termination (2095 Only) The data outputs of the M02095 are PECL compatible and any standard AC or DC-coupling termination technique can be used. Figure 4-7 and Figure 4-8 illustrate typical AC and DC terminations. AC-coupling is used in applications where the limiting amplifier is connected to a non-PECL compatible load. In addition to level shifting the signal to the common mode range of the load, the load receives the full PECL peak to peak swing from the limiting amplifier. DC-coupling can be used when driving PECL interfaces. In the case where the load does not contain PECL termination, Figure 4-8 shows the proper termination for the M02095 PECL outputs. A Thevenin termination may be substituted for the load when VCC-2V is not available and is shown in Figure 4-9. Figure 4-7. Most Common AC-Coupled PECL Termination (Non-PECL load) VCC RxOUTp 0.1µF Zo 100Ω M02095 RxOUTm 150Ω 0.1µF Zo DeSerializer 150Ω Zo = 50Ω 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 36 Applications Information Figure 4-8. True PECL Termination (DC Coupled) VCC RxOUTp M02095 RxOUTm Zo Zo DeSerializer 50Ω 50Ω Zo = 50Ω 10 nF VCC - 2V Figure 4-9. Thevenin Equivalent PECL Termination (DC Coupled) VCC VCC 10 nF RxOUTp Zo M02095 RxOUTm Zo 130Ω 130Ω 82Ω 82Ω DeSerializer Zo = 50Ω 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 37 Applications Information 4.4 Table 4-3. M02095/6 Configuration Logic M02095/6 Configuration Logic Config1 Config2 Config3 Config4 DIS/EN LOS=JAM/ NO_JAM LOS/ST SCB RxPOL TxPOL Special Config. 0 0 0 0 0 0 0 0 0 0 none 0 0 0 M 0 0 0 0 0 1 none 0 0 M 0 0 0 0 0 1 0 none 0 0 M M 0 0 0 0 1 1 none 0 0 1 1 0 0 0 1 0 0 none 0 0 0 1 0 0 0 1 0 1 none 0 0 1 0 0 0 0 1 1 0 none 0 0 M 1 0 0 0 1 1 1 none 0 0 1 M 0 0 0 0 0 0 SC1 0 M 0 0 0 0 1 0 0 0 none 0 M 0 M 0 0 1 0 0 1 none 0 M M 0 0 0 1 0 1 0 none 0 M M M 0 0 1 0 1 1 none 0 M 1 1 0 0 1 1 0 0 none 0 M 0 1 0 0 1 1 0 1 none 0 M 1 0 0 0 1 1 1 0 none 0 M M 1 0 0 1 1 1 1 none 0 M 1 M 0 0 1 0 0 0 SC2 M 0 0 0 0 1 0 0 0 0 none M 0 0 M 0 1 0 0 0 1 none M 0 M 0 0 1 0 0 1 0 none M 0 M M 0 1 0 0 1 1 none M 0 1 1 0 1 0 1 0 0 none M 0 0 1 0 1 0 1 0 1 none M 0 1 0 0 1 0 1 1 0 none M 0 M 1 0 1 0 1 1 1 none M 0 1 M 0 1 0 0 0 0 SC3 M M 0 0 0 1 1 0 0 0 none M M 0 M 0 1 1 0 0 1 none M M M 0 0 1 1 0 1 0 none M M M M 0 1 1 0 1 1 none M M 1 1 0 1 1 1 0 0 none M M 0 1 0 1 1 1 0 1 none 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 38 Applications Information Table 4-3. M02095/6 Configuration Logic Config1 Config2 Config3 Config4 DIS/EN LOS=JAM/ NO_JAM LOS/ST SCB RxPOL TxPOL Special Config. M M 1 0 0 1 1 1 1 0 none M M M 1 0 1 1 1 1 1 none M M 1 M 0 1 1 0 0 0 SC4 1 1 0 0 1 0 0 0 0 0 none 1 1 0 M 1 0 0 0 0 1 none 1 1 M 0 1 0 0 0 1 0 none 1 1 M M 1 0 0 0 1 1 none 1 1 1 1 1 0 0 1 0 0 none 1 1 0 1 1 0 0 1 0 1 none 1 1 1 0 1 0 0 1 1 0 none 1 1 M 1 1 0 0 1 1 1 none 1 1 1 M 1 0 0 0 0 0 SC5 0 1 0 0 1 0 1 0 0 0 none 0 1 0 M 1 0 1 0 0 1 none 0 1 M 0 1 0 1 0 1 0 none 0 1 M M 1 0 1 0 1 1 none 0 1 1 1 1 0 1 1 0 0 none 0 1 0 1 1 0 1 1 0 1 none 0 1 1 0 1 0 1 1 1 0 none 0 1 M 1 1 0 1 1 1 1 none 0 1 1 M 1 0 1 0 0 0 SC5 1 0 0 0 1 1 0 0 0 0 none 1 0 0 M 1 1 0 0 0 1 none 1 0 M 0 1 1 0 0 1 0 none 1 0 M M 1 1 0 0 1 1 none 1 0 1 1 1 1 0 1 0 0 none 1 0 0 1 1 1 0 1 0 1 none 1 0 1 0 1 1 0 1 1 0 none 1 0 M 1 1 1 0 1 1 1 none 1 0 1 M 1 1 0 0 0 0 SC6 M 1 0 0 1 1 1 0 0 0 none 1 M 0 0 1 1 1 0 0 0 SC7 M 1 0 M 1 1 1 0 0 1 none 1 M 0 M 1 1 1 0 0 1 SC8 M 1 M 0 1 1 1 0 1 0 none 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 39 Applications Information Table 4-3. M02095/6 Configuration Logic Config1 Config2 Config3 Config4 DIS/EN LOS=JAM/ NO_JAM LOS/ST SCB RxPOL TxPOL Special Config. 1 M M 0 1 1 1 0 1 0 SC9 M 1 M M 1 1 1 0 1 1 none 1 M M M 1 1 1 0 1 1 SC10 M 1 1 1 1 1 1 1 0 0 none 1 M 1 1 1 1 1 1 0 0 SC5 M 1 0 1 1 1 1 1 0 1 none 1 M 0 1 1 1 1 1 0 1 SC3 M 1 1 0 1 1 1 1 1 0 none 1 M 1 0 1 1 1 1 1 0 SC11 M 1 M 1 1 1 1 1 1 1 none M 1 1 M 1 1 1 0 0 0 SC12 1 M M 1 1 1 1 1 1 1 SC13 1 M 1 M 1 1 1 0 0 0 SC14 KEY: 0, 1, M:0 = Logic low; 1 = Logic high; M = pin floating (pin goes to intermediate “mid-range” self-biased voltage DIS/EN:0 = DIS pin acts as Tx_Disable; 1 = DIS pin becomes Tx_Enable LOS=JAM / NO_JAM:0 = Jam outputs upon LOS; 1 = Do not jam outputs upon LOS LOS/ST:0 = LOS-ST pin is ST (goes high with signal detect); 1 = LOS-ST pin is high with LOS SCB:0=latched fault; 1=safety circuit bypass mode TxPOL and RxPOL:0 = default polarity; 1 = inverted polarity Special Config.:Refer to Special Configurations table for definition of special configuration modes If Special Config = “none”, BIASMON, TxPwrMON and other functions operate as defined in the specification. 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 40 Applications Information Table 4-4. M02095/6 Special Configurations Special Config. # Special Config. Name SC1 Ignore_Ipin Safety logic ignores high/low faults on IPIN SC2 Vdet-RSSI Vdet node in limiting amp is muxed to BIASMON; RSSIPP node of limiting amp is muxed to TxPwrMON SC3 ModMon TxPwrMON output becomes MODMON output SC4 Faultbits6 BIASMON output acts as fault status at VCCTHL; TxPwrMON output acts as fault status at VCCTHH SC5 DCR_Filter (CAZ) The DC restore lowpass filter nodes are muxed to BIASMON and TxPwrMON; can add capacitance between these nodes to reduce the LF cutoff of the limiting amplifier SC6 Faultbits5 BIASMON output acts as fault status at VCC3THL; TxPwrMON output acts as fault status at VCC3THH SC7 Faultbits1 BIASMON output acts as fault status at OUTP; TxPwrMON output acts as fault status at IBOUT SC8 Faultbits2 BIASMON output acts as fault status at APCSET; TxPwrMON output acts as fault status at MODSET SC9 Faultbits3 BIASMON output acts as fault status at CAPC; TxPwrMON is undefined status bit SC10 Faultbits4 BIASMON output acts as fault status at Ipin_hi; TxPwrMON output acts as fault status at Ipin_lo SC11 Test Mode 1 SC12 DCRDIS SC13 Test Mode 2 Internal Use Only; do not use SC14 Test Mode 3 Internal Use Only; do not use 02095-DSH-001-E Definition Internal Use Only; do not use Disables the DC restore in the limiting amplifier. Can pass DC signal through limiting amp, but offset at limiting amplifier input passes through to outputs. Mindspeed Technologies® Mindspeed Proprietary and Confidential 41 5.0 Package Specification Figure 5-1. QFN32 Package Information Note: View is for a 28 pin package. All dimensions in the tables apply for the 32 pin package 3.15 3.15 3.30 3.30 3.45 3.45 0.90 0.70 02095-DSH-001-E Mindspeed Technologies® Mindspeed Proprietary and Confidential 42 www.mindspeed.com General Information: Telephone: (949) 579-3000 Headquarters - Newport Beach 4000 MacArthur Blvd., East Tower Newport Beach, CA 92660 © 2006-2007 Mindspeed Technologies®, Inc. All rights reserved. Information in this document is provided in connection with Mindspeed Technologies® ("Mindspeed®") products. These materials are provided by Mindspeed as a service to its customers and may be used for informational purposes only. Except as provided in Mindspeed’s Terms and Conditions of Sale for such products or in any separate agreement related to this document, Mindspeed assumes no liability whatsoever. Mindspeed assumes no responsibility for errors or omissions in these materials. Mindspeed may make changes to specifications and product descriptions at any time, without notice. Mindspeed makes no commitment to update the information and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to its specifications and product descriptions. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document. THESE MATERIALS ARE PROVIDED "AS IS" WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESS OR IMPLIED, RELATING TO SALE AND/OR USE OF MINDSPEED PRODUCTS INCLUDING LIABILITY OR WARRANTIES RELATING TO FITNESS FOR A PARTICULAR PURPOSE, CONSEQUENTIAL OR INCIDENTAL DAMAGES, MERCHANTABILITY, OR INFRINGEMENT OF ANY PATENT, COPYRIGHT OR OTHER INTELLECTUAL PROPERTY RIGHT. MINDSPEED FURTHER DOES NOT WARRANT THE ACCURACY OR COMPLETENESS OF THE INFORMATION, TEXT, GRAPHICS OR OTHER ITEMS CONTAINED WITHIN THESE MATERIALS. MINDSPEED SHALL NOT BE LIABLE FOR ANY SPECIAL, INDIRECT, INCIDENTAL, OR CONSEQUENTIAL DAMAGES, INCLUDING WITHOUT LIMITATION, LOST REVENUES OR LOST PROFITS, WHICH MAY RESULT FROM THE USE OF THESE MATERIALS. Mindspeed products are not intended for use in medical, lifesaving or life sustaining applications. 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