a FEATURES Easy to Use Single-Ended-to-Differential Conversion Adjustable Output Common-Mode Voltage Externally Adjustable Gain Low Harmonic Distortion –94 dBc—Second, <–114 dBc—Third @ 5 MHz into 800 ⍀ Load –87 dBc—Second, –85 dBc—Third @ 20 MHz into 800 ⍀ Load –3 dB Bandwidth of 320 MHz, G = +1 Fast Settling to 0.01% of 16 ns Slew Rate 1150 V/s Fast Overdrive Recovery of 4 ns Low Input Voltage Noise of 5 nV/√Hz 1 mV Typical Offset Voltage Wide Supply Range +3 V to ⴞ5 V Low Power 90 mW on 5 V 0.1 dB Gain Flatness to 40 MHz Available in 8-Lead SOIC and MICRO_SOIC APPLICATIONS ADC Driver Single-Ended-to-Differential Converter IF and Baseband Gain Block Differential Buffer Line Driver PRODUCT DESCRIPTION AD8138 is a major advancement over op amps for differential signal processing. The AD8138 can be used as a single-endedto-differential amplifier or as a differential-to-differential amplifier. The AD8138 is as easy to use as an op amp, and greatly simplifies differential signal amplification and driving. Manufactured on ADI’s proprietary XFCB bipolar process, the AD8138 has a –3 dB bandwidth of 320 MHz and delivers a differential signal with the lowest harmonic distortion available in a differential amplifier. The AD8138 has a unique internal feedback feature that provides output gain and phase matching that are balanced, suppressing even order harmonics. The internal feedback circuit also minimizes any gain error that would be associated with the mismatches in the external gain setting resistors. The AD8138’s differential output helps balance the input-todifferential ADCs, maximizing the performance of the ADC. The AD8138 eliminates the need for a transformer with high Low Distortion Differential ADC Driver AD8138 FUNCTIONAL BLOCK DIAGRAM 1 8 +IN VOCM 2 7 NC –IN V+ 3 6 V– +OUT 4 5 –OUT AD8138 NC = NO CONNECT TYPICAL APPLICATION CIRCUIT +5V +5V 499⍀ VIN 499⍀ + VOCM 499⍀ AIN DVDD DIGITAL OUTPUTS ADC AD8138 AIN – AVDD AVSS VREF 499⍀ performance ADCs, preserving the low frequency and dc information. The common-mode level of the differential output is adjustable by a voltage on the VOCM pin, easily level-shifting the input signals for driving single supply ADCs. Fast overload recovery preserves sampling accuracy. The AD8138 distortion performance makes it an ideal ADC driver for communication systems, with distortion performance good enough to drive state-of-the-art 10- to 16-bit converters at high frequencies. The AD8138’s high bandwidth and IP3 also make it appropriate for use as a gain block in IF and baseband signal chains. The AD8138 offset and dynamic performance make it well suited for a wide variety of signal processing and data acquisition applications. The AD8138 is available in both SOIC and MICRO_SOIC packages for operation over –40°C to +85°C temperatures. REV. C 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. 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 © Analog Devices, Inc., 2001 AD8138–SPECIFICATIONS (@ 25ⴗC, VS = ⴞ5 V, VOCM = 0, G = +1, RL,dm = 500 ⍀, unless otherwise noted. Refer to Figure 1 for test setup and label descriptions. All specifications refer to single-ended input and differential outputs unless otherwise noted.) Parameter Conditions Min VOUT = 0.5 V p-p, CF = 0 pF VOUT = 0.5 V p-p, CF = 1 pF VOUT = 0.5 V p-p, CF = 0 pF VOUT = 2 V p-p, CF = 0 pF VOUT = 2 V p-p, CF = 0 pF 0.01%, VOUT = 2 V p-p, CF = 1 pF VIN = 5 V to 0 V Step, G = +2 290 AD8138 Typ Max Unit ⴞDIN to ⴞOUT Specifications DYNAMIC PERFORMANCE –3 dB Small Signal Bandwidth Bandwidth for 0.1 dB Flatness Large Signal Bandwidth Slew Rate Settling Time Overdrive Recovery Time NOISE/HARMONIC PERFORMANCE Second Harmonic Third Harmonic IMD IP3 Voltage Noise (RTI) Input Current Noise INPUT CHARACTERISTICS Offset Voltage VOUT = 2 V p-p, 5 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 20 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 70 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 5 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 20 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 70 MHz, RL,dm = 800 Ω 20 MHz 20 MHz f = 100 kHz to 40 MHz f = 100 kHz to 40 MHz VOS,dm = VOUT,dm/2; VDIN+ = VDIN– = VOCM = 0 V TMIN–TMAX Variation –2.5 Input Bias Current Input Resistance Input Capacitance Input Common-Mode Voltage CMRR OUTPUT CHARACTERISTICS Output Voltage Swing Output Current Output Balance Error TMIN–TMAX Variation Differential Common Mode ∆VOUT,dm/∆VIN,cm; ∆VIN,cm = ± 1 V Maximum ∆VOUT; Single-Ended Output ∆VOUT,cm/∆VOUT,dm; ∆VOUT,dm = 1 V 320 225 30 265 1150 16 4 MHz MHz MHz MHz V/µs ns ns –94 –87 –62 –114 –85 –57 –77 37 5 2 dBc dBc dBc dBc dBc dBc dBc dBm nV/√Hz pA/√Hz ±1 ±4 3.5 –0.01 6 3 1 –4.7 to +3.4 –77 +2.5 7 –70 mV µV/°C µA µA/°C MΩ MΩ pF V dB 7.75 95 –66 V p-p mA dB 250 330 MHz V/µs VOCM to ⴞOUT Specifications DYNAMIC PERFORMANCE –3 dB Bandwidth Slew Rate DC PERFORMANCE Input Voltage Range Input Resistance Input Offset Voltage Input Bias Current VOCM CMRR Gain VOS,cm = VOUT,cm; VDIN+ = VDIN– = VOCM = 0 V [∆VOUT,dm/∆VOCM]; ∆VOCM = ± 1 V ∆VOUT,cm/∆VOCM; ∆VOCM = ± 1 V POWER SUPPLY Operating Range Quiescent Current Power Supply Rejection Ratio ± 3.8 200 –3.5 ±1 0.5 –75 0.9955 1 1.0045 ± 1.4 18 ± 5.5 23 TMIN to TMAX Variation ∆VOUT,dm/∆VS; ∆VS = ± 1 V OPERATING TEMPERATURE RANGE 20 40 –90 –40 +3.5 V kΩ mV µA dB V/V –70 V mA µA/°C dB +85 °C NOTES Harmonic Distortion Performance is equal or slightly worse with higher values of R L,dm. See TPCs 13 and 14 for more information. Specifications subject to change without notice. –2– REV. C AD8138 (@ 25ⴗC, V = 5 V, V = 2.5 V, G = +1, R = 500 ⍀, unless otherwise noted. Refer to Figure 1 for test SPECIFICATIONS setup and label descriptions. All specifications refer to single-ended input and differential outputs unless otherwise noted.) S Parameter OCM L,dm Conditions Min VOUT = 0.5 V p-p, CF = 0 pF VOUT = 0.5 V p-p, CF = 1 pF VOUT = 0.5 V p-p, CF = 0 pF VOUT = 2 V p-p, CF = 0 pF VOUT = 2 V p-p, CF = 0 pF 0.01%, VOUT = 2 V p-p, CF = 1 pF VIN = 2.5 V to 0 V Step, G = +2 280 AD8138 Typ Max Unit ⴞDIN to ⴞOUT Specifications DYNAMIC PERFORMANCE –3 dB Small Signal Bandwidth Bandwidth for 0.1 dB Flatness Large Signal Bandwidth Slew Rate Settling Time Overdrive Recovery Time NOISE/HARMONIC PERFORMANCE Second Harmonic Third Harmonic IMD IP3 Voltage Noise (RTI) Input Current Noise INPUT CHARACTERISTICS Offset Voltage VOUT = 2 V p-p, 5 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 20 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 70 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 5 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 20 MHz, RL,dm = 800 Ω VOUT = 2 V p-p, 70 MHz, RL,dm = 800 Ω 20 MHz 20 MHz f = 100 kHz to 40 MHz f = 100 kHz to 40 MHz VOS,dm = VOUT,dm/2; VDIN+ = VDIN– = VOCM = 2.5 V TMIN–TMAX Variation –2.5 Input Bias Current Input Resistance Input Capacitance Input Common-Mode Voltage CMRR OUTPUT CHARACTERISTICS Output Voltage Swing Output Current Output Balance Error TMIN–TMAX Variation Differential Common Mode ∆VOUT,dm/∆VIN,cm; ∆VIN,cm = 1 V Maximum ∆VOUT; Single-Ended Output 310 225 29 265 950 16 4 MHz MHz MHz MHz V/µs ns ns –90 –79 –60 –100 –82 –53 –74 35 5 2 dBc dBc dBc dBc dBc dBc dBc dBm nV/√Hz pA/√Hz ±1 ±4 3.5 –0.01 6 3 1 0.3 to 3.2 –77 +2.5 7 –70 mV µV/°C µA µA/°C MΩ MΩ pF V dB 2.9 95 –65 V p-p mA dB DYNAMIC PERFORMANCE –3 dB Bandwidth Slew Rate 220 250 MHz V/µs DC PERFORMANCE Input Voltage Range Input Resistance Input Offset Voltage 1.0 to 3.8 100 ±1 V kΩ ∆VOUT,cm/∆VOUT,dm; ∆VOUT,dm = 1 V VOCM to ⴞOUT Specifications Input Bias Current VOCM CMRR Gain –5 [∆VOUT,dm/∆VOCM]; ∆VOCM = 2.5 ± 1 V ∆VOUT,cm/∆VOCM; ∆VOCM = 2.5 ± 1 V 0.5 –70 0.9968 1 1.0032 2.7 15 11 21 POWER SUPPLY Operating Range Quiescent Current Power Supply Rejection Ratio TMIN to TMAX Variation ∆VOUT,dm/∆VS; ∆VS = ± 1 V OPERATING TEMPERATURE RANGE 20 40 –90 –40 NOTES Harmonic Distortion Performance is equal or slightly worse with higher values of R L,dm. See Figures TPC 13 and 14 for more information. Specifications subject to change without notice. REV. C +5 VOS,cm = VOUT,cm; VDIN+ = VDIN– = VOCM = 2.5 V –3– mV µA dB V/V –70 V mA µA/°C dB +85 °C AD8138 ABSOLUTE MAXIMUM RATINGS 1 PIN FUNCTION DESCRIPTIONS Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ± 5.5 V VOCM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ± VS Internal Power Dissipation . . . . . . . . . . . . . . . . . . . . 550 mW θJA2 (SOIC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155°C/W Operating Temperature Range . . . . . . . . . . . –40°C to +85°C Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C Lead Temperature (Soldering 10 sec) . . . . . . . . . . . . . 300°C Pin No. Name 1 2 NOTES 1 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 listed in the operational section of this specification is not implied. Exposure to Absolute Maximum Ratings for any extended periods may affect device reliability. 2 Thermal resistance measured on SEMI standard 4-layer board. 3 4 5 6 7 8 RF = 499⍀ Function –IN VOCM Negative Input Summing Node Voltage applied to this pin sets the commonmode output voltage with a ratio of 1:1. For example, 1 V dc on VOCM will set the dc bias level on +OUT and –OUT to 1 V. V+ Positive Supply Voltage +OUT Positive Output. Note: the voltage at –DIN is inverted at +OUT. –OUT Negative Output. Note: the voltage at +DIN is inverted at –OUT. V– Negative Supply Voltage NC No Connect +IN Positive Input Summing Node RG = 499⍀ 49.9⍀ RG = 499⍀ 24.9⍀ AD8138 RL,dm = 499⍀ PIN CONFIGURATION RF = 499⍀ 1 8 +IN VOCM 2 7 NC –IN Figure 1. Basic Test Circuit V+ 3 6 V– +OUT 4 5 –OUT AD8138 NC = NO CONNECT ORDERING GUIDE Model AD8138AR AD8138AR-REEL1 AD8138AR-REEL72 AD8138ARM AD8138ARM-REEL3 AD8138ARM-REEL72 AD8138-EVAL Temperature Range Package Descriptions Package Options –40°C to +85°C –40°C to +85°C –40°C to +85°C –40°C to +85°C –40°C to +85°C –40°C to +85°C 8-Lead SOIC 8-Lead SOIC 8-Lead SOIC 8-Lead MICRO_SOIC 8-Lead SOIC 8-Lead SOIC Evaluation Board SO-8 13" Tape and Reel 7" Tape and Reel RM-8 13" Tape and Reel 7" Tape and Reel SOIC Branding Information HBA HBA HBA NOTES 1 13" Reels of 2500 each. 2 7" Reels of 1000 each. 3 13" Reels of 3000 each. 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 AD8138 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– WARNING! ESD SENSITIVE DEVICE REV. C Typical Performance Characteristics–AD8138 Unless otherwise noted, GAIN = 1, RG = RF = RL,dm = 499 ⍀, TA = 25ⴗC; Refer to Figure 1 for test setup. 6 6 0.5 VS = ⴞ5V VIN = 0.2V p-p VIN = 0.2V p-p CF = 0pF 3 3 0.3 CF = 0pF 0 VS = ⴞ5V –3 GAIN – dB CF = 0pF GAIN – dB VS = +5V GAIN – dB VS = ⴞ5V VIN = 0.2V p-p 0 CF = 1pF –3 0.1 –0.1 CF = 1pF –6 –6 –9 –0.3 –9 10 100 FREQUENCY – MHz 1 1000 TPC 1. Small Signal Frequency Response –0.5 1 10 100 FREQUENCY – MHz 30 VIN = 2V p-p VS = ⴞ5V 3 G = 10, RF = 4.99k⍀ 3 VS = +5V 20 VS = ⴞ5V –3 GAIN – dB GAIN – dB CF = 0pF 0 0 CF = 1pF –3 VS = ⴞ5V CF = 0pF VOUT,dm = 0.2V p-p RG = 499⍀ G = 5, RF = 2.49k⍀ 10 G = 2, RF = 1k⍀ G = 1, RF = 499⍀ 0 –6 100 TPC 3. 0.1 dB Flatness vs. Frequency 6 VIN = 2V p-p CF = 0pF –6 –9 –9 10 100 FREQUENCY – MHz 1000 TPC 4. Large Signal Frequency Response DISTORTION – dBc HD2(VS = ⴞ5V) –90 –100 HD3(VS = +5V) –110 –120 0 10 20 30 40 50 60 FUNDAMENTAL FREQUENCY – MHz TPC 7. Harmonic Distortion vs. Frequency REV. C TPC 6. Small Signal Frequency Response for Various Gains –30 70 –40 HD3(VS = +5V) –60 –70 HD2(VS = +5V) –80 HD2(VS = ⴞ5V) –90 –100 HD3(VS = ⴞ5V) –110 1000 10 100 FREQUENCY – MHz 1 VOUT,dm = 4V p-p RL = 800⍀ –50 HD2(VS = +5V) –80 1000 –40 VOUT,dm = 2V p-p RL = 800⍀ –70 10 100 FREQUENCY – MHz TPC 5. Large Signal Frequency Response –50 –60 –10 1 DISTORTION – dBc 1 DISTORTION – dBc 10 FREQUENCY – MHz 1 TPC 2. Small Signal Frequency Response 6 GAIN – dB 1000 HD3(VS = ⴞ5V) 0 10 20 30 40 50 60 FUNDAMENTAL FREQUENCY – MHz TPC 8. Harmonic Distortion vs. Frequency –5– 70 VOUT,dm = 2V p-p RL = 800⍀ FO = 20MHz –50 HD2(VS = +5) –60 HD3(VS = +5) –70 –80 HD3(VS = ⴞ5) –90 HD2(VS = ⴞ5) –100 –4 –3 –2 –1 0 1 2 VOCM DC OUTPUT – Volts 3 TPC 9. Harmonic Distortion vs. VOCM 4 AD8138 –70 –60 –60 VS = ⴞ5V RL = 800⍀ HD3(F = 20MHz) –70 HD2(F = 20MHz) –80 –90 HD2(F = 5MHz) –100 –80 HD3(F = 20MHz) –90 HD2(F = 5MHz) –100 HD3(F = 5MHz) HD3(F = 5MHz) –110 –80 –90 HD2(F = 5MHz) –100 HD3(F = 5MHz) –110 0 1 2 3 4 –120 6 5 DIFFERENTIAL OUTPUT VOLTAGE – V p-p TPC 10. Harmonic Distortion vs. Differential Output Voltage 1 0 2 3 4 –110 0.25 DIFFERENTIAL OUTPUT VOLTAGE – V p-p TPC 11. Harmonic Distortion vs. Differential Output Voltage –60 –60 VS = +5V VOUT,dm = 2V p-p 0.50 0.75 1.00 1.25 1.50 1.75 DIFFERENTIAL OUTPUT VOLTAGE – V p-p TPC 12. Harmonic Distortion vs. Differential Output Voltage 10 VS = ⴞ5V VOUT,dm = 2V p-p –70 –70 FC = 50MHz VS = ⴞ5V –10 HD2(F = 20MHz) DISTORTION – dBc HD2(F = 20MHz) DISTORTION – dBc HD2(F = 20MHz) –80 HD3(F = 20MHz) –90 HD2(F = 5MHz) HD3(F = 20MHz) –80 –90 HD2(F = 5MHz) –100 POUT – dBm –120 HD3(F = 20MHz) –70 HD2(F = 20MHz) DISTORTION – dBc DISTORTION – dBc VS = +3V RL = 800⍀ VS = +5V RL = 800⍀ DISTORTION – dBc –60 –30 –50 –70 HD3(F = 5MHz) –100 –110 HD3(F = 5MHz) –110 200 600 1000 1400 –90 –120 200 1800 600 RLOAD – ⍀ 1000 1400 RLOAD – ⍀ 1800 TPC 14. Harmonic Distortion vs. RLOAD TPC 13. Harmonic Distortion vs. RLOAD –110 49.5 49.7 49.9 50.1 50.3 FREQUENCY – MHz TPC 15. Intermodulation Distortion VS = ⴞ5V 45 RL = 800⍀ 50.5 CF = 0pF VOUT,dm = 0.2V p-p VS = ⴞ5V VOUT,dm INTERCEPT – dBm 40 CF = 1pF VOUT– VS = +5V 35 VOUT+ VS = ⴞ5V V+DIN 30 1V 25 0 20 40 60 5ns 40mV 5ns 80 FREQUENCY – MHz TPC 16. Third Order Intercept vs. Frequency TPC 17. Large Signal Transient Response –6– TPC 18. Small Signal Transient Response REV. C AD8138 VS = ⴞ5V CF = 0pF VOUT,dm = 2V p-p CF = 0pF VS = ⴞ5V CF = 1pF 200V VOUT,dm = 2V p-p VS = ⴞ5V VOUT,dm VS = +5V CF = 1pF V+DIN 400mV 400mV 5ns 5ns 1V TPC 20. Large Signal Transient Response TPC 19. Large Signal Transient Response 4ns TPC 21. Settling Time VS = ⴞ5V CF = 0pF CL = 10pF CL = 5pF VOUT,dm 499⍀ VS = ⴞ5V F = 20MHz V+DIN = 8V p-p G = 3(RF = 1500) 499⍀ 49.9⍀ 499⍀ 24.9⍀ CL = 20pF 24.9⍀ AD8138 24.9⍀ CL 453⍀ 499⍀ V+DIN 4V 400mV 30ns TPC 23. Test Circuit for Cap Load Drive TPC 22. Output Overdrive TPC 24. Large Signal Transient Response for Various Cap Loads –20 –20 VS = ⴞ5V ⌬VOUT,dm/⌬VIN,cm –30 2.5ns VIN = 2V p-p CMRR – dB –40 499⍀ 49.9⍀ 499⍀ –50 24.9⍀ –60 249⍀ AD8138 249⍀ 499⍀ BALANCE ERROR – dB –30 499⍀ –40 VS = ⴞ5V –50 –60 –70 VS = +5V –80 –70 1 10 100 FREQUENCY – MHz TPC 25. CMRR vs. Frequency REV. C 1k 1 TPC 26. Test Circuit for Output Balance –7– 10 100 FREQUENCY – MHz 1k TPC 27. Output Balance Error vs. Frequency AD8138 5.0 100 ⌬VOUT,dm/⌬VS DIFFERENTIAL OUTPUT OFFSET – mV –10 SINGLE-ENDED OUTPUT –20 –40 –50 –60 +PSRR (VS = +5V, 0V AND ⴞ5V) –70 10 VS = +5 1 VS = ⴞ5V –80 0.1 –90 1 10 100 FREQUENCY – MHz 1k 1 VS = ⴞ5V VS = +5V 0 VS = +3V –2.5 –5.0 –40 –20 40 0 20 60 TEMPERATURE – ⴗC 80 100 TPC 30. Output Referred Differential Offset Voltage vs. Temperature 6 30 5 VS = +5V SUPPLY CURRENT – mA BIAS CURRENT – A 100 TPC 29. Output Impedance vs. Frequency TPC 28. PSRR vs. Frequency 4 VS = ⴞ5V, +5V 3 VS = +3V 2 1 –40 10 FREQUENCY – MHz 2.5 VS = ⴞ5V 20 VS = +5V 15 40 0 20 60 TEMPERATURE – ⴗC 80 TPC 31. Input Bias Current vs. Temperature 100 0 –3 VS = +3V –6 10 –20 VS = ⴞ5V 3 25 GAIN – dB PSRR – dB IMPEDANCE – ⍀ –PSRR (VS = ⴞ5V) –30 5 –40 –9 –20 40 0 20 60 TEMPERATURE – ⴗC 80 100 TPC 32. Supply Current vs. Temperature 1 10 100 FREQUENCY – MHz 1k TPC 33. VOCM Frequency Response VS = ⴞ5V VOCM = –1V TO +1V VOUT,cm 400mV 5ns TPC 34. VOCM Transient Response –8– REV. C AD8138 OPERATIONAL DESCRIPTION Definition of Terms CF RF +DIN RG +IN AD8138 VOCM –DIN –OUT RG –IN RL,dm VOUT,dm +OUT RF CF Figure 2. Circuit Definitions Differential voltage refers to the difference between two node voltages. For example, the output differential voltage (or equivalently output differential-mode voltage) is defined as: VOUT,dm = (V+OUT – V–OUT) V+OUT and V–OUT refer to the voltages at the +OUT and –OUT terminals with respect to a common reference. Common-mode voltage refers to the average of two node voltages. The output common-mode voltage is defined as: VOUT,cm = (V+OUT + V–OUT)/2 Balance is a measure of how well differential signals are matched in amplitude and exactly 180 degrees apart in phase. Balance is most easily determined by placing a well-matched resistor divider between the differential voltage nodes and comparing the magnitude of the signal at the divider’s midpoint with the magnitude of the differential signal. (See TPC 26.) By this definition, output balance is the magnitude of the output common-mode voltage divided by the magnitude of the output differential-mode voltage: Output Balance Error = Analyzing an Application Circuit The AD8138 uses high open-loop gain and negative feedback to force its differential and common-mode output voltages in such a way as to minimize the differential and common-mode error voltages. The differential error voltage is defined as the voltage between the differential inputs labeled +IN and –IN in Figure 2. For most purposes, this voltage can be assumed to be zero. Similarly, the difference between the actual output commonmode voltage and the voltage applied to VOCM can also be assumed to be zero. Starting from these two assumptions, any application circuit can be analyzed. Setting the Closed Loop Gain Neglecting the capacitors CF, the differential mode gain of the circuit in Figure 2 can be determined to be described by the following equation: VOUT , cm VOUT , dm VIN , dm VOUT , dm THEORY OF OPERATION The AD8138 differs from conventional op amps in that it has two outputs whose voltages move in opposite directions. Like an op amp, it relies on high open loop gain and negative feedback to force these outputs to the desired voltages. The AD8138 behaves much like a standard voltage feedback op amp and makes it easy to perform single-ended-to-differential conversion, common-mode level-shifting, and amplification of differential signals. Also like an op amp, the AD8138 has high input impedance and low output impedance. Previous differential drivers, both discrete and integrated designs, have been based on using two independent amplifiers, and two independent feedback loops, one to control each of the outputs. When these circuits are driven from a single-ended source, the resulting outputs are typically not well balanced. Achieving a balanced output has typically required exceptional matching of the amplifiers and feedback networks. DC common-mode level-shifting has also been difficult with previous differential drivers. Level-shifting has required the use of a third amplifier and feedback loop to control the output common-mode level. Sometimes the third amplifier has also been used to attempt to correct an inherently unbalanced REV. C circuit. Excellent performance over a wide frequency range has proven difficult with this approach. The AD8138 uses two feedback loops to separately control the differential and common-mode output voltages. The differential feedback, set with external resistors, controls only the differential output voltage. The common-mode feedback controls only the common-mode output voltage. This architecture makes it easy to arbitrarily set the output common-mode level. It is forced, by internal common-mode feedback, to be equal to the voltage applied to the VOCM input, without affecting the differential output voltage. The AD8138 architecture results in outputs that are very highly balanced over a wide frequency range without requiring tightly matched external components. The common-mode feedback loop forces the signal component of the output common-mode voltage to be zeroed. The result is nearly perfectly balanced differential outputs, of identical amplitude and exactly 180 degrees apart in phase. = RF S RG S This assumes the input resistors, RGS and feedback resistors, RFS on each side are equal. Estimating the Output Noise Voltage Similar to the case of a conventional op amp, the differential output errors (noise and offset voltages) can be estimated by multiplying the input referred terms, at +IN and –IN, by the circuit noise gain. The noise gain is defined as: R GN = 1 + F RG To compute the total output referred noise for the circuit of Figure 2, consideration must also be given to the contribution of the resistors RF and RG. Refer to Table I for estimated output noise voltage densities at various closed-loop gains. Table I Gain RG RF (⍀) (⍀) Bandwidth Output Noise –3 dB 8138 Only Output Noise 8138 + RG, RF 1 2 5 10 499 499 499 499 320 MHz 180 MHz 70 MHz 30 MHz 11.5 nV/√Hz 16.6 nV/√Hz 31.6 nV/√Hz 56.6 nV/√Hz –9– 499 1.0 k 2.49 k 4.99 k 10 nV/√Hz 15 nV/√Hz 30 nV/√Hz 55 nV/√Hz AD8138 The Impact of Mismatches in the Feedback Networks Setting the Output Common-Mode Voltage As mentioned previously, even if the external feedback networks (RF/RG) are mismatched, the internal common-mode feedback loop will still force the outputs to remain balanced. The amplitudes of the signals at each output will remain equal and 180 degrees out of phase. The input-to-output differential-mode gain will vary proportionately to the feedback mismatch, but the output balance will be unaffected. The AD8138’s VOCM pin is internally biased at a voltage approximately equal to the midsupply point (average value of the voltages on V+ and V–). Relying on this internal bias will result in an output common-mode voltage that is within about 100 mV of the expected value. Ratio matching errors in the external resistors will result in a degradation of the circuit’s ability to reject input common-mode signals, much the same as for a four-resistor difference amplifier made from a conventional op amp. Also, if the dc levels of the input and output common-mode voltages are different, matching errors will result in a small differential-mode output offset voltage. For G = 1 case, with a ground referenced input signal and the output common-mode level set for 2.5 V, an output offset of as much as 25 mV (1% of the difference in common-mode levels) can result if 1% tolerance resistors are used. Resistors of 1% tolerance will result in a worst case input CMRR of about 40 dB, worst-case differential mode output offset of 25 mV due to 2.5 V level-shift, and no significant degradation in output balance error. Calculating an Application Circuit’s Input Impedance The effective input impedance of a circuit such as that in Figure 2, at +DIN and –DIN, will depend on whether the amplifier is being driven by a single-ended or differential signal source. For balanced differential input signals, the input impedance (RIN,dm) between the inputs (+DIN and –DIN) is simply: RIN,dm = 2 × RG In the case of a single-ended input signal (for example if –DIN is grounded and the input signal is applied to +DIN), the input impedance becomes: RIN , dm RG = RF 1 − 2 × RG + RF ( ) In cases where more accurate control of the output common-mode level is required, it is recommended that an external source, or resistor divider (made up of 10 kΩ resistors), be used. The output common-mode offset specified on pages 2 and 3 assume the VOCM input is driven by a low impedance voltage source. Driving a Capacitive Load A purely capacitive load can react with the pin and bondwire inductance of the AD8138 resulting in high frequency ringing in the pulse response. One way to minimize this effect is to place a small capacitor across each of the feedback resistors. The added capacitance should be small to avoid destabilizing the amplifier. An alternative technique is to place a small resistor in series with the amplifier’s outputs as shown in TPC 23. LAYOUT, GROUNDING AND BYPASSING As a high speed part, the AD8138 is sensitive to the PCB environment in which it has to operate. Realizing its superior specifications requires attention to various details of good high speed PCB design. The first requirement is for a good solid ground plane that covers as much of the board area around the AD8138 as possible. The only exception to this is that the two input pins (Pins 1 and 8) should be kept a few mm from the ground plane, and ground should be removed from inner layers and the opposite side of the board under the input pins. This will minimize the stray capacitance on these nodes and help preserve the gain flatness versus frequency. The power supply pins should be bypassed as close as possible to the device to the nearby ground plane. Good high frequency ceramic chip capacitors should be used. This bypassing should be done with a capacitance value of 0.01 µF to 0.1 µF for each supply. Further away, low frequency bypassing should be provided with 10 µF tantalum capacitors from each supply to ground. The circuit’s input impedance is effectively higher than it would be for a conventional op amp connected as an inverter because a fraction of the differential output voltage appears at the inputs as a common-mode signal, partially bootstrapping the voltage across the input resistor RG. Input Common-Mode Voltage Range in Single Supply Applications The AD8138 is optimized for level-shifting “ground” referenced input signals. For a single-ended input this would imply, for example, that the voltage at –DIN in Figure 1 would be zero volts when the amplifier’s negative power supply voltage (at V–) was also set to zero volts. The signal routing should be short and direct in order to avoid parasitic effects. Wherever there are complementary signals, a symmetrical layout should be provided to the extent possible to maximize the balance performance. When running differential signals over a long distance, the traces on PCB should be close together or any differential wiring should be twisted together to minimize the area of the loop that is formed. This will reduce the radiated energy and make the circuit less susceptible to interference. –10– REV. C AD8138 BALANCED TRANSFORMER DRIVER SIGNAL WILL BE COUPLED ON THIS SIDE VIA CSTRAY Transformers are among the oldest devices that have been used to perform a single-ended-to-differential conversion (and vice versa). Transformers also can perform the additional functions of galvanic isolation, step-up or step-down of voltages and impedance transformation. For these reasons, transformers will always find uses in certain applications. CSTRAY VUNBAL 52.3⍀ PRIMARY CSTRAY However, when driving a transformer single-endedly and then looking at its output, there is a fundamental imbalance due to the parasitics inherent in the transformer. The primary (or driven) side of the transformer has one side at dc potential (usually ground), while the other side is driven. This can cause problems in systems that require good balance of the transformer’s differential output signals. NO SIGNAL IS COUPLED ON THIS SIDE Figure 3. Transformer Single-Ended-to-Differential Converter Is Inherently Imbalanced 499⍀ If the interwinding capacitance (CSTRAY) is assumed to be uniformly distributed, a signal from the driving source will couple to the secondary output terminal that is closest to the primary’s driven side. On the other hand, no signal will be coupled to the opposite terminal of the secondary, because its nearest primary terminal is not driven. (See Figure 3.) The exact amount of this imbalance will depend on the particular parasitics of the transformer, but will mostly be a problem at higher frequencies. CSTRAY 49.9⍀ 499⍀ +IN OUT– VUNBAL AD8138 499⍀ 500⍀ 0.005% VDIFF 500⍀ 0.005% OUT+ –IN 49.9⍀ CSTRAY 499⍀ The balance of a differential circuit can be measured by connecting an equal-valued resistive voltage divider across the differential outputs and then measuring the center point of the circuit with respect ground. Since the two differential outputs are supposed to be of equal amplitude, but 180 degrees opposite phase, there should be no signal present for perfectly balanced outputs. Figure 4. AD8138 Forms a Balanced Transformer Driver 0 OUTPUT BALANCE ERROR – dB The circuit in Figure 3 shows a Minicircuits T1-6T transformer connected with its primary driven single-endedly and the secondary connected with a precision voltage divider across its terminals. The voltage divider is made up of two 500 Ω, 0.005% precision resistors. The voltage VUNBAL, which is also equal to the ac common-mode voltage, is a measure of how closely the outputs are balanced. The plots in Figure 5 show a comparison between the case where the transformer is driven single-endedly by a signal generator and driven differentially using an AD8138. The top signal trace of Figure 5 shows the balance of the single-ended configuration, while the bottom shows the differentially driven balance response. The 100 MHz balance is 35 dB better when using the AD8138. –20 –40 VUNBAL, FOR TRANSFORMER WITH SINGLE-ENDED DRIVE –60 –80 VUNBAL, DIFFERENTIAL DRIVE –100 0.3 The well-balanced outputs of the AD8138 will provide a drive signal to each of the transformer’s primary inputs that are of equal amplitude and 180 degrees out of phase. Thus, depending on how the polarity of the secondary is connected, the signals that conduct across the interwinding capacitance will either both assist the transformer’s secondary signal equally, or both buck the secondary signals. In either case, the parasitic effect will be symmetrical and provide a well-balanced transformer output. (See Figure 5.) REV. C 500⍀ 0.005% 500⍀ SECONDARY VDIFF 0.005% 1 10 FREQUENCY – MHz 100 500 Figure 5. Output Balance Error for Circuits of Figures 3 and 4 –11– AD8138 HIGH-PERFORMANCE ADC DRIVING The circuit in Figure 6 shows a simplified front-end connection for an AD8138 driving an AD9224, a 12-bit, 40 MSPS A/D converter. The A/D works best when driven differentially, which minimizes its distortion as described in its data sheet. The AD8138 eliminates the need for a transformer to drive the ADC and performs single-ended-to-differential conversion, common-mode level-shifting and buffering of the driving signal. The positive and negative outputs of the AD8138 are connected to the respective differential inputs of the AD9224 via a pair of 49.9 Ω resistors to minimize the effects of the switched-capacitor front-end of the AD9224. For best distortion performance it is run from supplies of ± 5 V. The AD8138 is configured with unity gain for a single-ended input-to-differential output. The additional 23 Ω, 523 Ω total, at the input to –IN is to balance the parallel impedance of the 50 Ω source and its 50 Ω termination that drives the noninverting input. The signal generator has a ground-referenced, bipolar output, i.e., it drives symmetrically above and below ground. Connecting VOCM to the CML pin of the AD9224 sets the output commonmode of the AD8138 at 2.5 V, which is the midsupply level for the AD9224. This voltage is bypassed by a 0.1 µF capacitor. The full-scale analog input range of the AD9224 is set to 4 V p-p, by shorting the SENSE terminal to AVSS. This has been determined to be the scaling to provide minimum harmonic distortion. For the AD8138 to swing a 4 V p-p, each output swings 2 V p-p, while providing signals that are 180 degrees out of phase. With a common-mode voltage at the output of 2.5 V, this means that each AD8138 output will swing between 1.5 V and 3.5 V. A ground-referenced 4 V p-p, 5 MHz signal at DIN+ was used to test the circuit in Figure 6. When the combined-device circuit was run with a sampling rate of 20 MHz MSPS, the SFDR (spurious free dynamic range) was measured at –85 dBc. +5V +5V 0.1pF 499⍀ 499⍀ 50⍀ SOURCE 49.9⍀ + VINB 0.1pF AVDD DRVDD VOCM 49.9⍀ 523⍀ AD8138 DIGITAL OUTPUTS AD9224 49.9⍀ VINA AVSS SENSE CML DRVSS 0.1pF 499⍀ –5V Figure 6. AD8138 Driving an AD9224, a 12-Bit, 40 MSPS A/D Converter –12– REV. C AD8138 The circuit was tested with a –0.5 dBFS signal at various frequencies. Figure 8 shows a plot of the total harmonic distortion (THD) vs. frequency at signal amplitudes of 1 V and 2 V differential drive levels. 3 V OPERATION The circuit in Figure 7 shows a simplified front end connection for an AD8138 driving an AD9203, a 10-bit, 40 MSPS A/D converter that is specified to work on a single 3 V supply. The A/D works best when driven differentially to make the best use of the signal swing available within the 3 V supply. The appropriate outputs of the AD8138 are connected to the appropriate differential inputs of the AD9203 via a low-pass filter. –40 –45 The AD8138 is configured for unity gain for a single-ended input to differential output. The additional 23 Ω at the input to –IN is to balance the impedance of the 50 Ω source and its 50 Ω termination that drives the noninverting input. THD – dBc –50 The signal generator has ground-referenced, bipolar output, i.e., it can drive symmetrically above and below ground. Even though the AD8138 has ground as its negative supply, it can still function as a level-shifter with such an input signal. AD8138-2V –60 –65 AD8138-1V –70 –75 The output common-mode is raised up to midsupply by the voltage divider that biases VOCM. In this way, the AD8138 provides dc-coupling and level-shifting of a bipolar signal, without inverting the input signal. –80 0 5 10 15 FREQUENCY – MHz 20 25 Figure 8. AD9203 THD @ –0.5 dBFS AD8138 The low-pass filter between the AD8138 and the AD9203 provides filtering that helps to improve the signal-to-noise ratio. Lower noise can be realized by lowering the pole frequency, but the bandwidth of the circuit will be lowered. +3V –55 Figure 9 shows the signal to noise plus distortion (SINAD) under the same conditions as above. For the smaller signal swing, the AD8138 performance is quite good, but its performance degrades when trying to swing too close to the supply rails. +3V 0.1F 499⍀ 65 0.1F 0.1F 63 10k⍀ 61 49.9⍀ 49.9⍀ + AD8138 523⍀ 20pF 49.9⍀ AVDD AINN DRVDD AD9203 AINP DIGITAL OUTPUTS AVSS DRVSS 20pF 0.1F 499⍀ 59 SINAD – dBc 499⍀ 57 AD8138-1V 55 AD8138-2V 53 10k⍀ 51 49 Figure 7. AD8138 Driving an AD9203, a 10-Bit, 40 MSPS A/D Converter 47 45 0 5 10 15 FREQUENCY – MHz 20 25 Figure 9. AD9203 SINAD @ –0.5 dBFS AD8138 REV. C –13– AD8138 OUTLINE DIMENSIONS Dimensions shown in inches and (mm). 8-Lead SOIC (SO-8) 0.1968 (5.00) 0.1890 (4.80) 0.1574 (4.00) 0.1497 (3.80) 8 5 1 4 PIN 1 0.0098 (0.25) 0.0040 (0.10) 0.2440 (6.20) 0.2284 (5.80) 0.0688 (1.75) 0.0532 (1.35) 0.0196 (0.50) x 45° 0.0099 (0.25) 0.0500 0.0192 (0.49) SEATING (1.27) 0.0098 (0.25) PLANE BSC 0.0138 (0.35) 0.0075 (0.19) 8° 0° 0.0500 (1.27) 0.0160 (0.41) 8-Lead MICRO_SOIC (RM-8) 0.122 (3.10) 0.114 (2.90) 8 5 0.199 (5.05) 0.187 (4.75) 0.122 (3.10) 0.114 (2.90) 1 4 PIN 1 0.0256 (0.65) BSC 0.120 (3.05) 0.112 (2.84) 0.006 (0.15) 0.002 (0.05) 0.018 (0.46) SEATING 0.008 (0.20) PLANE 0.120 (3.05) 0.112 (2.84) 0.043 (1.09) 0.037 (0.94) 0.011 (0.28) 0.003 (0.08) 33ⴗ 27ⴗ 0.028 (0.71) 0.016 (0.41) AD8138–Revision History Location Page Data Sheet changed from REV. B to REV. C. Edits to SPECIFICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–3 Edits to ORDERING GUIDE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 –14– REV. C –15– –16– PRINTED IN U.S.A. C01073–0–6/01(C)