45 dB Digitally Controlled VGA LF to 600 MHz AD8369* FEATURES Digitally Controlled Variable Gain in 3 dB Steps –5 dB to +40 dB (RL = 1 k⍀) –10 dB to +35 dB (RL = 200 ⍀) Less than 0.2 dB Flatness over a +20 MHz Bandwidth up to 380 MHz 4-Bit Parallel or 3-Wire Serial Interface Differential 200 ⍀ Input and Output Impedance Single 3.0 V–5.5 V Supply Draws 37 mA at 5 V Power-Down <1 mA Maximum APPLICATIONS Cellular/PCS Base Stations IF Sampling Receivers Fixed Wireless Access Wireline Modems Instrumentation PRODUCT DESCRIPTION The AD8369 is a high performance digitally controlled variable gain amplifier (VGA) for use from low frequencies to a –3 dB frequency of 600 MHz at all gain codes. The AD8369 delivers excellent distortion performance: the two-tone, third-order intermodulation distortion is –69 dBc at 70 MHz for a 1 V p-p composite output into a 1 kW load. The AD8369 has a nominal noise figure of 7 dB when at maximum gain, then increases with decreasing gain. Output IP3 is +19.5 dBm at 70 MHz into a 1 kW load and remains fairly constant over the gain range. The signal input is applied to pins INHI and INLO. Variable gain is achieved via two methods. The 6 dB gain steps are implemented using a discrete X-AMP® structure, in which the input signal is progressively attenuated by a 200 W R-2R ladder network that also sets the input impedance; the 3 dB steps are implemented at the output of the amplifier. This combination provides very accurate 3 dB gain steps over a span of 45 dB. The output impedance is set by on-chip resistors across the differential output pins, FUNCTIONAL BLOCK DIAGRAM BIT3 BIT2 DENB SENB BIT1 BIT0 GAIN CODE DECODE 3dB STEP BIAS VPOS PWUP FILT OPHI Gm CELLS OPLO INHI CMDC INLO COMM COMM OPHI and OPLO. The overall gain depends upon the source and load impedances due to the resistive nature of the input and output ports. Digital control of the AD8369 is achieved using either a serial or a parallel interface. The mode of digital control is selected by connecting a single pin (SENB) to ground or the positive supply. Digital control pins can be driven with standard CMOS logic levels. The AD8369 may be powered on or off by a logic level applied to the PWUP pin. For a logic high, the chip powers up rapidly to its nominal quiescent current of 37 mA at 25ºC. When low, the total dissipation drops to less than a few milliwatts. The AD8369 is fabricated on an Analog Devices proprietary, high performance 25 GHz silicon bipolar IC process and is available in a 16-lead TSSOP package for the industrial temperature range of –40∞C to +85∞C. A populated evaluation board is available. *Patents Pending REV. 0 Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective companies. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781/329-4700 www.analog.com Fax: 781/326-8703 © 2002 Analog Devices, Inc. All rights reserved. (V = 5 V, T = 25ⴗC, R = 200 ⍀, R = 1000 ⍀, Frequency = 70 MHz, at maximum gain, otherwise noted.) AD8369–SPECIFICATIONS unless S S L Parameter Conditions Min OVERALL FUNCTION Frequency Range 3 dB Bandwidth LF* GAIN CONTROL INTERFACE Voltage Gain Span Maximum Gain Minimum Gain Gain Step Size Gain Step Accuracy Gain Step Response Time INPUT STAGE Input Resistance Input Capacitance All bits high (1 1 1 1) All bits low (0 0 0 0) Over entire gain range, with respect to 3 dB step Step = 3 dB, settling to 10% of final value From INHI to INLO From INHI to COMM, from INLO to COMM From INHI to INLO From INHI to COMM, from INLO to COMM Input Noise Spectral Density Input Common-Mode DC Voltage Measured at pin CMDC Maximum Linear Input |VINHI – VINLO| at Minimum Gain OUTPUT STAGE Output Resistance Output Capacitance Common-Mode DC Voltage Slew Rate POWER INTERFACE Supply Voltage Quiescent Current vs. Temperature Disable Current vs. Temperature POWER UP INTERFACE Enable Threshold Disable Threshold Response Time Input Bias Current From OPHI to OPLO From OPHI to COMM, from OPLO to COMM From OPHI to OPLO From OPHI to COMM, from OPLO to COMM No input signal Output step = 1 V Typ Unit 600 MHz 45 40 –5 3 ± 0.05 30 dB dB dB dB dB ns 200 100 0.1 1.1 2 1.7 2.2 W W pF pF nV/÷Hz V V 200 100 0.25 1.5 VS/2 1200 W W pF pF V V/ms 3.0 PWUP high –40∞C £ TA £ 85∞C PWUP low –40∞C £ TA £ 85∞C Max 5.5 42 52 750 1 V mA mA mA mA 1.0 7 V V ms 160 mA 37 400 Pin PWUP 2.2 Time delay following low to high transition on PWUP until output settles to within 10% of final value PWUP = 5 V DIGITAL INTERFACE Pins SENB, BIT0, BIT1, BIT2, BIT3, and DENB Low Condition High Condition Input Bias Current Frequency = 10 MHz Voltage Gain Gain Flatness Noise Figure Output IP3 IMD3 Harmonic Distortion P1dB 2.0 150 V V mA 40.5 +0.05* 7.0 +22 +22 dB dB dB dBV rms dBm –74 –72 –71 +3 +3 dBc dBc dBc dBV rms dBm 3.0 Low input Within ± 10 MHz of 10 MHz f1 = 9.945 MHz, f2 = 10.550 MHz f1 = 9.945 MHz, f2 = 10.550 MHz VOPHI – VOPLO = 1 V p-p composite Second-Order, VOPHI – VOPLO = 1 V p-p Third-Order, VOPHI – VOPLO = 1 V p-p For ± 1 dB deviation from linear gain *The low frequency high-pass corner is determined by the capacitor on pin FILT, C FILT. See the Theory of Operation section for details. –2– REV. 0 AD8369 SPECIFICATIONS (Continued) Parameter Conditions Frequency = 70 MHz Voltage Gain Gain Flatness Noise Figure Output IP3 Within ± 20 MHz of 70 MHz IMD3 Harmonic Distortion P1dB Frequency = 140 MHz Voltage Gain Gain Flatness Noise Figure Output IP3 IMD3 Harmonic Distortion P1dB Frequency = 190 MHz Voltage Gain Gain Flatness Noise Figure Output IP3 IMD3 Harmonic Distortion P1dB Frequency = 240 MHz Voltage Gain Gain Flatness Noise Figure Output IP3 IMD3 Harmonic Distortion P1dB Frequency = 320 MHz Voltage Gain Gain Flatness Noise Figure Output IP3 IMD3 Harmonic Distortion P1dB REV. 0 Min f1 = 69.3 MHz, f2 = 70.7 MHz f1 = 69.3 MHz, f2 = 70.7 MHz VOPHI – VOPLO = 1 V p-p composite Second-Order, VOPHI – VOPLO = 1 V p-p Third-Order, VOPHI – VOPLO = 1 V p-p For ± 1 dB deviation from linear gain Within ± 20 MHz of 140 MHz f1 = 139.55 MHz, f2 = 140.45 MHz f1 = 139.55 MHz, f2 = 140.45 MHz VOPHI – VOPLO = 1 V p-p composite Second-Order, VOPHI – VOPLO = 1 V p-p Third-Order, VOPHI – VOPLO = 1 V p-p For ±1 dB deviation from linear gain Within ± 20 MHz of 190 MHz f1 = 189.55 MHz, f2 = 190.45 MHz f1 = 189.55 MHz, f2 = 190.45 MHz VOPHI – VOPLO = 1 V p-p composite Second-Order, VOPHI – VOPLO = 1 V p-p Third-Order, VOPHI – VOPLO = 1 V p-p For ± 1 dB deviation from linear gain Within ± 20 MHz of 240 MHz f1 = 239.55 MHz, f2 = 240.45 MHz f1 = 239.55 MHz, f2 = 240.45 MHz VOPHI – VOPLO = 1 V p-p composite Second-Order, VOPHI – VOPLO = 1 V p-p Third-Order, VOPHI – VOPLO = 1 V p-p For ± 1 dB deviation from linear gain Within ± 20 MHz of 320 MHz f1 = 319.55 MHz, f2 = 320.45 MHz f1 = 319.55 MHz, f2 = 320.45 MHz VOPHI – VOPLO = 1 V p-p composite Second-Order, VOPHI – VOPLO = 1 V p-p Third-Order, VOPHI – VOPLO = 1 V p-p For ± 1 dB deviation from linear gain –3– Typ Max Unit 40.5 ± 0.1 7.0 +19.5 +19.5 dB dB dB dBV rms dBm –69 –68 –64 +3 +3 dBc dBc dBc dBV rms dBm 40.0 ± 0.10 7.0 +17 +17 dB dB dB dBV rms dBm –64 –63 –55 +3 +3 dBc dBc dBc dBV rms dBm 39.7 ± 0.1 7.2 +15.5 +15.5 dB dB dB dBV rms dBm –61 –57 –51 +2 +2 dBc dBc dBc dBV rms dBm 39.3 ± 0.1 7.2 +14 +14 dB dB dB dBV rms dBm –58 –50 –49 +1.5 +1.5 dBc dBc dBc dBV rms dBm 39.0 ± 0.15 7.4 +11.5 +11.5 dB dB dB dBV rms dBm –53 –47 –49 +1.0 +1.0 dBc dBc dBc dBV rms dBm AD8369 SPECIFICATIONS (Continued) Parameter Conditions Min Frequency = 380 MHz Voltage Gain Gain Flatness Noise Figure Output IP3 Within ± 20 MHz of 380 MHz Typ f1 = 379.55 MHz, f2 = 380.45 MHz IMD3 f1 = 379.55 MHz, f2 = 380.45 MHz, VOPHI – VOPLO = 1 V p-p composite Second-Order, VOPHI – VOPLO = 1 V p-p Third-Order, VOPHI – VOPLO = 1 V p-p For ± 1 dB deviation from linear gain Harmonic Distortion P1dB Max Unit 38.5 ± 0.15 7.8 +8.5 +8.5 dB dB dB dBV rms dBm –47 –45 –49 +0.5 +0.5 dBc dBc dBc dBV rms dBm Specifications subject to change without notice. TIMING SPECIFICATIONS SERIAL PROGRAMMING TIMING REQUIREMENTS (VS = 5 V, T = 25∞C) Parameter Typ Unit Minimum Clock Pulsewidth (TPW) Minimum Clock Period (TCK) Minimum Setup Time Data vs. Clock (TDS) Minimum Setup Time Data Enable vs. Clock (TES) Minimum Hold Time Clock vs. Data Enable (TEH) Minimum Hold Time Data vs. Clock (TDH) 10 20 2 2 2 4 ns ns ns ns ns ns PARALLEL PROGRAMMING TIMING REQUIREMENTS (VS = 5 V, T = 25∞C) Parameter Typ Unit Minimum Setup Time Data Enable vs. Data (TES) Minimum Hold Time Data Enable vs. Data (TEH) Minimum Data Enable Width (TPW) 2 2 4 ns ns ns TDS DATA (BIT 0) MSB–1 (BIT2) TDH MSB MSB (BIT3) MSB–1 MSB–2 LSB MSB–2 (BIT1) TPW TCK LSB (BIT0) CLOCK (BIT 1) TES TES DATA ENABLE (DENB) CLOCK DISABLED TEH TPW TEH CLOCK DISABLED CLOCK ENABLED DATA IS LATCHED ON LOW-TO-HIGH TRANSITION OF DENB (NOT TO SCALE) Serial Programming Timing DENB DATA IS LATCHED ON HIGH-TO-LOW TRANSITION OF DENB (NOT TO SCALE) Parallel Programming Timing –4– REV. 0 AD8369 ABSOLUTE MAXIMUM RATINGS* Table I. Typical Voltage Gain vs. Gain Code (VS = 5 V, f = 70 MHz) Supply Voltage VS, VPOS . . . . . . . . . . . . . . . . . . . . . . . . 5.5 V PWUP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VS + 200 mV BIT0, BIT1, BIT2, BIT3, DENB, SENB . . . . . . VS + 200 mV Input Voltage, VINHI – VINLO . . . . . . . . . . . . . . . . . . . . . . . . 4 V Input Voltage, VINHI or VINLO with respect to COMM . . 4.5 V Input Voltage, VINHI – VINLO with respect to COMM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . COMM – 200 mV Internal Power Dissipation . . . . . . . . . . . . . . . . . . . . . 265 mW JA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150∞C/W Maximum Junction Temperature . . . . . . . . . . . . . . . . . 125∞C Operating Temperature Range . . . . . . . . . . . . –40∞C to +85∞C Storage Temperature Range . . . . . . . . . . . . . –65∞C to +150∞C Lead Temperature Range (soldering 60 sec) . . . . . . . to 300∞C *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 condition s above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Gain Code Typical Gain (dB) BIT3 BIT2 BIT1 BIT0 RL = 1 k⍀ Typical Gain (dB) RL = 200 ⍀ 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 –10 –7 –4 –1 2 5 8 11 14 17 20 23 26 29 32 35 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 –5 –2 1 4 7 10 13 16 19 22 25 28 31 34 37 40 ORDERING GUIDE Model Temperature Range AD8369ARU –40ºC to +85ºC AD8369ARU-REEL7 –40ºC to +85ºC AD8369EVAL Package Description Package Option Tube, 16-Lead TSSOP 7" Tape and Reel Evaluation Board RU-16 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 AD8369 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. REV. 0 –5– AD8369 PIN CONFIGURATION 16 INHI INLO 1 COMM 2 BIT0 3 AD8369 14 PWUP BIT1 4 TOP VIEW (Not To Scale) 13 VPOS BIT2 5 15 COMM 12 SENB BIT3 6 11 FILT DENB 7 10 CMDC OPLO 8 9 OPHI PIN FUNCTION DESCRIPTIONS Pin No. Mnemonic Function 1 INLO Balanced Differential Input. Internally biased, should be ac-coupled. 2 COMM Device Common. Connect to low impedance ground. 3 BIT0 Gain Selection Least Significant Bit. Used as DATA input signal when in serial mode of operation. 4 BIT1 Gain Selection Control Bit. Used as CLOCK input pin when in serial mode of operation. 5 BIT2 Gain Selection Control Bit. Inactive when in serial mode of operation. 6 BIT3 Gain Selection Most Significant Bit. Inactive when in serial mode of operation. 7 DENB Data Enable Pin. Writes data to register. See Timing Specifications for details. 8 OPLO Balanced Differential Output. Biased to midsupply, should be ac-coupled. 9 OPHI Balanced Differential Output. Biased to midsupply, should be ac-coupled. 10 CMDC Common-Mode Decoupling Pin. Connect bypass capacitor to ground for additional common-mode supply decoupling beyond the existing internal decoupling. 11 FILT High-Pass Filter Connection. Used to set high-pass corner frequency. 12 SENB Serial or Parallel Interface Select. Connect SENB to VPOS for serial operation. Connect SENB to COMM for parallel operation. 13 VPOS Positive Supply Voltage, VS = +3 V to +5.5 V. 14 PWUP Power-Up Pin. Connect PWUP to VPOS to power up the device. Connect PWUP to COMM to power-down. 15 COMM Device Common. Connect to a low impedance ground. 16 INHI Balanced Differential Input. Internally biased, should be ac-coupled. –6– REV. 0 Typical Performance Characteristics–AD8369 (VS = 5 V, T = 25ⴗC, RS = 200 ⍀, Maximum gain, unless otherwise noted.) 50 50 40 40 30 30 RL = 1k⍀ GAIN – dB GAIN – dB GAIN CODE 15 20 RL = 200⍀ 10 20 10 0 0 ⴚ10 ⴚ10 ⴚ20 GAIN CODE 0 ⴚ20 0 1 2 3 4 5 6 7 8 9 GAIN CODE 10 10 11 12 13 14 15 100 FREQUENCY – MHz 1000 TPC 4. Gain vs. Frequency by Gain Code, RL = 1 kW TPC 1. Gain vs. Gain Code at 70 MHz 50 43 41 VS = 5V, RL = 1k⍀ 40 GAIN CODE 15 39 VS = 3V, RL = 1k⍀ 30 VS = 5V, RL = 200⍀ 35 GAIN – dB GAIN – dB 37 VS = 3V, RL = 200⍀ 33 20 10 31 0 29 ⴚ10 27 GAIN CODE 0 ⴚ20 25 10 1000 28 21 35 28 26 19 30 23 24 17 25 18 22 15 20 13 20 13 15 8 18 11 10 3 16 9 5 7 0 14 0 1 2 3 4 5 6 7 8 9 GAIN CODE OUTPUT IP3 – dBm OUTPUT IP3 – dBV rms OUTPUT IP3 – dBm 1000 TPC 5. Gain vs. Frequency by Gain Code, RL = 200 W TPC 2. Maximum Gain vs. Frequency by RL and Supply Voltage –2 –7 10 10 11 12 13 14 15 100 FREQUENCY – MHz 1000 TPC 6. Output IP3 vs. Frequency, VS = 5 V, RL = 200 W Maximum Gain TPC 3. Output IP3 vs. Gain Code at 70 MHz, VS = 5 V, RL = 200 W REV. 0 100 FREQUENCY – MHz OUTPUT IP3 – dBV rms 100 FREQUENCY – MHz 10 –7– AD8369 –63 –20 –64 –30 OUTPUT IMD – dBc OUTPUT IMD – dBc –65 –66 –67 –40 –50 –60 –68 –70 –69 –80 –70 0 1 2 3 4 5 6 7 8 9 GAIN CODE 10 11 12 13 14 15 0 ⴚ40 ⴚ35 ⴚ45 ⴚ40 ⴚ50 HD3 ⴚ55 100 150 200 250 300 350 400 450 500 550 600 FREQUENCY – MHz TPC 10. Two-Tone IMD3 vs. Frequency VOPHI – VOPLO = 1 V p-p, VS = 5 V, RL = 1 kW, Maximum Gain HARMONIC DISTORTION – dBc HARMONIC DISTORTION – dBc TPC 7. Two-Tone, IMD3 vs. Gain Code at 70 MHz, VOPHI – VOPLO = 1 V p-p, VS = 5 V, RL = 1 kW 50 HD2 ⴚ60 ⴚ65 ⴚ70 ⴚ45 HD3 ⴚ50 HD2 ⴚ55 ⴚ60 ⴚ65 ⴚ75 ⴚ70 0 100 50 150 200 250 FREQUENCY – MHz 300 350 400 0 TPC 8. Harmonic Distortion at VOPHI – VOPLO = 1 V p-p vs. Frequency, VS = 5 V, RL = 1 kW, Maximum Gain 50 100 150 200 250 FREQUENCY – MHz 300 350 400 TPC 11. Harmonic Distortion at VOPHI – VOPLO = 1 V p-p vs. Frequency, VS = 5 V, RL = 200 W, Maximum Gain 8.0 50 7.8 40 NOISE FIGURE – dB NOISE FIGURE – dB 5V 30 20 7.6 3V 7.4 7.2 RL = 1k⍀ 7.0 10 RL = 200⍀ 6.8 0 6.6 0 1 2 3 4 5 6 7 8 9 GAIN CODE 10 11 12 13 14 15 0 50 100 150 200 250 FREQUENCY – MHz 300 350 400 TPC 12. Noise Figure vs. Frequency by RL and Supply Voltage at Maximum Gain TPC 9. Noise Figure vs. Gain Code at 70 MHz, VS = 5 V, RL = 200 W –8– REV. 0 2.0 9 2 8.5 1.5 8 1 8.0 1.0 7 0 7.5 0.5 6 –1 7.0 0 5 –2 6.5 –0.5 4 –3 6.0 –1.0 5.5 –1.5 3 –4 5.0 –2.0 2 –5 4.5 –2.5 1 –6 4.0 –3.0 0 0 1 2 3 4 5 6 7 8 9 GAIN CODE P1dB – dBm 10 11 12 13 14 15 10 TPC 13. Output P1dB vs. Gain Code at 70 MHz, VS = 5 V, RL = 200 W –7 1000 TPC 16. Output P1dB vs. Frequency, VS = 5 V, RL = 200 W, Maximum Gain ⴚ40 80 70 ⴚ50 REVERSE ISOLATION – dB 60 CMRR – dB 100 FREQUENCY – MHz P1dB – dBV rms 9.0 P1dB – dBV rms P1dB – dBm AD8369 50 40 30 20 ⴚ60 ⴚ70 ⴚ80 ⴚ90 10 ⴚ100 0 100 FREQUENCY – MHz 10 1000 TPC 14. Common-Mode Rejection Ratio vs. Frequency at Maximum Gain, VS = 5 V, RL = 200 W (Refer to Appendix for Definition) 250 100 FREQUENCY – MHz 10 1000 TPC 17. Reverse Isolation vs. Frequency at Maximum Gain, VS = 5 V, RL = 200 W (Refer to Appendix for Definition) 0.75 250 0.75 0.25 INLO 200 0.50 C OPHI 150 0.25 C 100 10 100 FREQUENCY – MHz 10 TPC 15. Equivalent Input Resistance and Capacitance vs. Frequency at Maximum Gain REV. 0 OPLO 100 0 1000 100 FREQUENCY – MHz 0 1000 TPC 18. Equivalent Output Resistance and Capacitance vs. Frequency at Maximum Gain –9– CAPACITANCE – pF 150 R RESISTANCE – ⍀ 0.50 INHI CAPACITANCE – pF RESISTANCE – ⍀ R 200 AD8369 90 90 60 120 150 750MHz 10MHz 750MHz 180 150 30 GAIN CODE 15 0 500MHz GAIN CODE 15 30 10MHz 0 180 380MHz GAIN CODES 0, 1, AND 9 60 120 GAIN CODES 0, 1, AND 9 330 210 380MHz 500MHz 330 210 240 240 300 270 300 270 TPC 19. Differential Input Reflection Coefficient, S11, ZO = 50 W Differential, Selected Gain Codes TPC 22. Differential Output Reflection Coefficient, S22, ZO = 50 W Differential, Selected Gain Codes AVERAGE OF 128 SAMPLES INPUT = 250mV p-p, 10MHz DIFFERENTIAL OUTPUT 250mV/VERTICAL DIVISION OVERDRIVE OUTPUT 1V/VERTICAL DIVISION ZERO RECOVERY ZERO BIT 3 2V/VERTICAL DIVISION BIT 0 2V/VERTICAL DIVISION GND GND TIME – 1s/DIV TIME – 20ns/DIV TPC 20. Gain Step Time Domain Response, 3 dB Step, VS = 5 V, RL = 1 kW, Parallel Transparent Mode TPC 23. Overdrive Recovery, Maximum Gain, VS = 5 V, RL = 1 kW, Parallel Transparent Mode DIFFERENTIAL OUTPUT 200mV/DIV ZERO DIFFERENTIAL OUTPUT 70MHz, 750mV/DIV ZERO INPUT 2mV/DIV PWUP 2V/VERTICAL DIVISION GND GND TIME – 2s/DIV TIME – 20s/DIV TPC 21. PWUP Time Domain Response, Maximum Gain, VS = 5 V, RL = 1 kW TPC 24. Pulse Response, Maximum Gain, VS = 5 V, RL = 1 k W –10– REV. 0 2.0 2.0 1.5 1.5 1.0 1.0 0.5 GAIN ERROR – dB ⴚ40ⴗC 0 ⴙ85ⴗC ⴚ0.5 ⴚ1.0 0 ⴚ0.5 ⴙ85ⴗC ⴚ1.0 GAIN ERROR AT ⴚ40ⴗC AND ⴙ85ⴗC WITH RESPECT TO ⴙ25ⴗC. DATA BASED ON 45 PARTS FROM TWO BATCH LOTS. ⴚ1.5 ⴚ2.0 10 ⴚ1.5 100 FREQUENCY – MHz ⴚ2.0 1000 TPC 25. Gain Error Due to Temperature Change vs. Frequency, 3 Sigma to Either Side of Mean, VS = 5 V, RL = 1 kW, Maximum Gain 2.0 1.5 1.5 10 100 FREQUENCY – MHz GAIN ERROR – dB 0 ⴚ0.5 ⴚ1.0 ⴚ40ⴗC 0.5 0 ⴚ0.5 ⴚ1.0 GAIN ERROR AT ⴚ40ⴗC AND ⴙ85ⴗC WITH RESPECT TO ⴙ25ⴗC. DATA BASED ON 45 PARTS FROM TWO BATCH LOTS. ⴚ1.5 10 ⴙ85ⴗC 100 FREQUENCY – MHz 35 30 GAIN ERROR AT ⴚ40ⴗC AND ⴙ85ⴗC WITH RESPECT TO ⴙ25ⴗC. DATA BASED ON 45 PARTS FROM TWO BATCH LOTS. ⴙ85ⴗC ⴚ1.5 ⴚ2.0 1000 TPC 26. Gain Error Due to Temperature Change vs. Frequency, 3 Sigma to Either Side of Mean, VS = 3 V, RL = 1 kW, Maximum Gain 10 100 FREQUENCY – MHz 28 10 23 8 3 ⴙ85ⴗC –40ⴗC 15 8 +85ⴗC 3 10 –2 5 0 10 100 FREQUENCY – MHz ⴙ25ⴗC 6 P1dB – dBm 13 20 OUTPUT IP3 – dBV rms OUTPUT IP3 – dBm 18 25 1000 TPC 29. Gain Error Due to Temperature Change vs. Frequency, 3 Sigma to Either Side of Mean, VS = 3 V, RL = 200 W, Maximum Gain +25ⴗC ⴚ40ⴗC 4 1 –1 –3 2 –5 0 –7 –2 –7 1000 10 TPC 27. IP3 vs. Frequency by Temperature, VS = 5 V, RL = 200 W, Maximum Gain REV. 0 1000 1.0 ⴚ40ⴗC 0.5 ⴚ2.0 GAIN ERROR AT ⴚ40ⴗC AND ⴙ85ⴗC WITH RESPECT TO ⴙ25ⴗC. DATA BASED ON 45 PARTS FROM TWO BATCH LOTS. TPC 28. Gain Error Due to Temperature Change vs. Frequency, 3 Sigma to Either Side of Mean, VS = 5 V, RL = 200 W, Maximum Gain 2.0 1.0 GAIN ERROR – dB ⴚ40ⴗC 0.5 100 FREQUENCY – MHz –9 1000 TPC 30. Output P1dB vs. Frequency by Temperature, VS = 5 V, RL = 200 W, Maximum Gain –11– P1dB – dBV rms GAIN ERROR – dB AD8369 AD8369 60 40 SAMPLE FROM ONE BATCH LOT SAMPLE FROM ONE BATCH LOT 35 50 30 PART COUNT PART COUNT 40 30 20 25 20 15 10 10 5 0 3.06 0 3.08 3.10 3.12 GAIN STEP SIZE – dB/CODE 3.16 3.14 TPC 31. Distribution of Gain Step Size, 70 MHz, VS = 5 V 3.18 3.20 GAIN STEP SIZE – dB/CODE 3.22 TPC 34. Distribution of Gain Step Size, 320 MHz, VS = 5 V 18 26 SAMPLE FROM TWO BATCH LOTS 16 SAMPLE FROM TWO BATCH LOTS 24 22 14 20 18 PART COUNT PART COUNT 12 10 8 6 16 14 12 10 8 6 4 4 2 2 0 –74 –73 –72 –71 –70 –69 –68 –67 –66 –65 –64 –63 –62 IMD – dBc 0 –58 TPC 32. Distribution of IMD3, 70 MHz, RL = 1 kW, VOPHI – VOPLO = 1 V p-p Composite, VS = 5 V, Maximum Gain –57 –56 –55 –54 –53 –52 IMD – dBc –51 –50 –49 –48 TPC 35. Distribution of IMD3, 320 MHz, RL = 1 kW, VOPHI – VOPLO = 1 V p-p Composite, VS = 5 V, Maximum Gain 3000 1600 2500 1400 GROUP DELAY – ps GROUP DELAY – ps 3V, RL = 1k⍀ 2000 5V, RL = 1k⍀ 1500 3V, RL = 200⍀ 1000 1200 1000 ALL GAIN CODES REPRESENTED 800 5V, RL = 200⍀ 500 600 400 0 0 100 200 300 400 500 FREQUENCY – MHz 600 700 0 800 TPC 33. Group Delay vs. Frequency by RL and Supply Voltage at Maximum Gain 100 200 300 400 500 FREQUENCY – MHz 600 700 800 TPC 36. Group Delay vs. Frequency by Gain Code, VS = 5 V, RL = 1 kW, Maximum Gain –12– REV. 0 AD8369 100 90 80 PSSR – dB 70 60 50 40 30 20 10 0 10 10000 100 1000 FREQUENCY – kHz TPC 37. Power Supply Rejection Ratio, VS = 5 V, RL = 1 kW, Maximum Gain VS DIGITAL GAIN STEP SELECTION OPHI 100⍀ FIXED GAIN Gm CELLS VS/2 VS 3dB SWITCHED ATTENUATOR 100⍀ OPLO INHI ~ VS 2 – 0.7 BIAS CMDC VS/2 20pF 22pF INLO Figure 1. General Block Diagram, Control and Signal Paths Are Differential THEORY OF OPERATION The AD8369 is a digitally controlled fully differential VGA based on a variation of Analog Devices’ patented X-AMP architecture (Figure 1). It provides accurate gain control over a 45 dB span with a constant –3 dB bandwidth of 600 MHz. The 3 dB gain steps can be controlled by a user-selectable parallel- or serial-mode digital interface. A single pin (SENB) selects the mode. The AD8369 is designed for optimal operation when used in a fully differential system, although single-ended operation is also possible. Its nominal input and output impedances are 200 W. Input Attenuator and Output 3 dB Step The AD8369 is comprised of a seven-stage R-2R ladder network (eight taps) and a selected Gm stage followed by a fixed-gain differential amplifier. The ladder provides a total attenuation of 42 dB in 6 dB steps. The full signal is applied to the amplifier using the first tap; at the second tap, the signal is 6 dB lower and so on. A further 3 dB interpolating gain step is introduced at the output of the fixed gain amplifier, providing the full 45 dB of gain span. Fixed Gain Amplifier The fixed gain amplifier is driven by the tap point of the R-2R ladder network via the selected Gm cell. The output stage is a REV. 0 complementary pair of current sources, loaded with internal 100 W resistors to ac ground which provides a 200 W differential output impedance. The low frequency gain of the AD8369 can be approximated by the equation: ˆ Ê 200 R L ˆ Ê VOUT 1 = 0.6 Á ˜ ˜ ÁÁ VIN Ë 200 + R L ¯ Ë (15 - n) ˜¯ 2 where RL is the external load resistor in ohms and n is the gain code; 0 is the minimum gain code and 15 is the maximum gain code. The external load, which is in parallel combination with the internal 200 W output resistor, affects the overall gain and peak output swing. Note that the external load has no effect on the gain step size. Input and Output Interfaces The dc working points of the differential input and output interfaces of the AD8369 are internally biased. The inputs INHI and INLO are biased to a diode drop below VS/2 (~1.7 V for a 5 V positive supply) to meet isolation and headroom constraints, while the outputs OPHI and OPLO are centered on the supply midpoint, VS/2, to provide the maximum output swing. The internal VS/2 reference and the CMDC reference are buffered and decoupled to ground via internal capacitors. The input bias voltage, derived from this VS/2 reference, is brought –13– AD8369 out to pin CMDC for decoupling to ground. An external capacitor from CMDC to COMM of 0.01 mF or more is recommended to lower the input common-mode impedance of the AD8369 and improve single-ended operation. shift registers are composed of four flip-flops that accept the serial data stream. TO GAIN CONTROL SECTION BIT0 Signals must be ac-coupled at the input, either via a pair of capacitors or a transformer. These may not be needed when the source has no dc path to ground, such as a SAW filter. The output may need dc blocking capacitors when driving dcgrounded loads, but it can be directly coupled to an ADC, provided that the common-mode levels are compatible. BIT1 BIT2 BIT3 GAIN CONTROL REGISTER (LATCH) T/H DENB MUX MUX MUX MUX A/B B The input and output resistances form a high-pass filter in combination with any external ac-coupling capacitors that should be chosen to minimize signal roll-off at low frequencies. For example, using input-coupling capacitors of 0.1 mF, each driving a 100 W input node (200 W differential), the –3 dB high-pass corner frequency is at: A B A B A B A SENB SHIFT REGISTER SHIFT REGISTER SHIFT REGISTER SHIFT REGISTER 1 = 16 kHz 2p(10 –7 )(100 ) It is important to note that the input and output resistances are subject to process variations of up to ± 20%. This will affect the high-pass corner frequencies and the overall gain when driven from, or loaded by, a finite impedance (see the Reducing Gain Sensitivity to Input and Output Impedance Variation section). BIT0 (DATA) BIT1 (CLOCK) BIT2 BIT3 Figure 2. Digital Interface Block Diagram In parallel operation, the 4-bit parallel data is placed on pins BIT3 through BIT0 and passed along to the gain control register via the mux. Data is latched into the gain control register on the falling edge of the input to DENB, subject to meeting the specified setup and hold times. If this pin is held high (> VS/2), any changes in the parallel data will result in a change in the gain, after propagation delays. This is referred to as the transparent mode of operation. If DENB is held low, the last 4-bit word in the gain control register will remain latched regardless of the signals at the data inputs. Noise and Distortion It is a common aspect of this style of VGAs, however implemented, that the effective noise figure worsens as the gain is reduced. The AD8369 uses a fixed gain amplifier, having a certain invariant noise spectral density, preceded by an attenuator. Thus, the noise figure increases simply by 6 dB per tap point, from a starting point of 7 dB at full gain. However, unlike voltage-controlled amplifiers that must necessarily invoke nonlinear elements in the signal path, the distortion in a step-gain amplifier can be very low and is essentially independent of the gain setting. Note that the postamplifier 3 dB step does not affect the noise performance, but it has some bearing on the output third-order intercept (OIP3). See TPCs 3 and 9. In serial operation, the BIT0 pin is used for data input while the BIT1 pin is the clock input. Data is loaded into the serial shift registers on the rising edge of the clock when DENB is low. Given the required setup and hold times are observed, four rising edge transitions of the clock will fully load the shift register. On the rising edge of DENB, the 4-bit word in the shift register is passed into the gain control register. While this pin is held high, the clock input to the shift registers is turned off. Once DENB is taken low, the shift register clock is again enabled and the last 4-bit word prior to enabling the clock will be latched into the gain control registers. This enables the loading of a new 4-bit gain control word without interruption of the signal path. Only when DENB goes high is data transferred from the shift registers to the gain control registers. If no connections are made to the digital control pins, internal 40 kW resistors pull these pins to levels that set the AD8369 to its minimum gain condition. Offset Control Loop The AD8369 uses a control loop to null offsets at the input. If left uncorrected, these offsets, in conjunction with the gain of the AD8369, would reduce the available voltage swing at the output. The control loop samples the differential output voltage error and feeds nulling currents back into the input stage. The nominal high-pass corner frequency of this loop is internally set to 520 kHz, but it is subject to process variations of up to ± 20%. This corner frequency can be reduced by adding an external capacitor from the FILT pin to ground, in parallel to an internal 30 pF capacitor. For example, an external capacitor of 0.1 mF would lower the high-pass corner by a factor of 30/100,030, to approximately 156 Hz. This frequency should be chosen to be at least one decade below the lowest component of interest in the input spectrum. Digital Control The gain of the AD8369 is controlled via a serial or parallel interface, as shown in Figure 2. Serial or parallel operation is selected via the SENB pin. Setting SENB to a logic low (< VS/2) selects parallel operation, while a logic high on SENB (> VS/2) selects serial operation. The AD8369 has two control registers, the gain control register and the shift register. The gain control register is a latch that holds the data that sets the amplifier gain. The At power-up or chip enable, if the AD8369 is in parallel mode and DENB is held low, the gain control register will come up in an indeterminate state. To avoid this, DENB should be held high with valid data present during power-up when operating in the parallel mode. In serial mode, the data in the gain control interface powers up with a random gain code independent of the DENB pin. Serial mode operation requires at least four clock cycles and the transition of DENB from low to high for valid data to be present at the gain control register. –14– REV. 0 AD8369 0.1F VS 3V TO 5.5V 0.1F 0.1F 16 15 0.1F 14 13 12 11 INHI COMM PWUP VPOS SENB INⴙ 10 9 0.1F FILT CMDC OPHI 50⍀ TX LINE RL RL AD8369 TC4-1W INLO COMM BIT0 0.1F 1 2 3 BIT1 BIT2 4 5 BIT3 DENB OPLO 6 7 8 0.1F CONTROL INTERFACE Figure 3. Basic Connections BASIC CONNECTIONS Figure 3 shows the minimum connections required for basic operation of the AD8369. Supply voltages of between +3 V and +5.5 V are permissible. The supply to the VPOS pin should be decoupled with at least one low inductance surface-mount ceramic capacitor of 0.1 mF placed as close as possible to the device. More effective decoupling is provided by placing a 100 pF capacitor in parallel and including a 4.7 W resistor in series with the supply. Attention should be paid to voltage drops. A ferrite bead is a better choice than the resistor where a smaller drop is required. Input-Output Interface A broadband 50 W input termination can be achieved by using a 1:2 turns-ratio transformer, as shown in Figure 3. This also can be used to convert a single-ended input signal to a balanced differential form at the inputs of the AD8369. In general, there is a loss factor, 1/(1+ ), at each interface so the overall gain reduction due to source and output loading is 40 log10 (1 + ). In this case, the input and output loss factors are 0.8 (1.94 dB) at each interface so the overall gain is reduced by 3.88 dB. Operation from a Single-Sided Source While there are distinct benefits of driving the AD8369 with a well-balanced input, in terms of distortion and gain conformance at high frequencies, satisfactory operation will often be possible when a single-sided source is ac-coupled directly to pin INHI, and pin INLO is ac-grounded via a second capacitor. This mode of operation takes advantage of the good HF common-mode rejection of the input system. The capacitor values are, as always, selected to ensure adequate transmission at low frequencies. As in all high frequency applications, the trace impedance should be maintained right up to the input pins by careful design of the PC board traces, as described in the PCB Layout Considerations section. Reducing Gain Sensitivity to Input and Output Impedance Variation 0.1F VS 0.1F 50⍀ 0.1F 16 15 0.1F 14 SOURCE The lot-to-lot variations in gain mentioned previously can, in principle, be eliminated by adjustments to the source and load. INLO COMM BIT0 RSOURCE = a (RINPUT ) ROUTPUT = a (RLOAD ) (RSOURCE ) (RLOAD ) = (RINPUT ) (ROUTPUT ) = 2002 REV. 0 12 11 10 9 0.1F FILT CMDC OPHI RL AD8369 Define a term as a function of the input and output resistances of the AD8369 and the source and load resistances presented to it: For a 50 W source, = 0.25. Then the load resistance for zero sensitivity to variations must be 800 W. Put more simply: 13 INHI COMM PWUP VPOS SENB 1 2 3 BIT1 BIT2 4 5 BIT3 DENB OPLO 6 7 8 0.1F 0.1F CONTROL INTERFACE Figure 4. Single-Ended-to-Differential Application Example –15– AD8369 For example, suppose the input signal in Figure 4 is a 140 MHz sinusoid from a ground-referenced 50 W source. The 0.1 mF coupling capacitors present a very low reactance at this frequency (11 mW) so that essentially all of the ac voltage is delivered to the differential inputs of the AD8369. It will be apparent that, in addition to the use of adequate coupling capacitance, the external capacitor used to extend the low frequency range of the offset control loop, CFILT, must also be large enough to prevent the offset control loop from attempting to track the ac signal fluctuations. Interfacing to an ADC The AD8369 can be used to effectively increase the dynamic range of an ADC in a direct IF sampling receiver application. Figure 5 provides an example of an interface to an ADC designed for an IF of 70 MHz. It comprises a low-pass filter that attenuates harmonics while providing an impedance transformation from 200 W to 1 kW. This impedance transformation allows the AD8369 to operate much below its peak output swing in the pass band, which significantly reduces distortion. 0.1F VS 0.1F 0.1F 270nH 16 15 14 13 12 11 INHI COMM PWUP VPOS SENB 10 9 0.1F FILT CMDC OPHI 6.8pF AD8369 INLO COMM BIT0 1 2 3 BIT1 BIT2 4 5 15pF ADC 1k⍀ BIT3 DENB OPLO 6 7 8 0.1F 270nH CONTROL INTERFACE Figure 5. AD8369 to ADC Interface A high performance 14-bit ADC, the AD6645, is used for illustrative purposes and is sampling at 64 MSPs with a full-scale input of 2.2 V p-p. Typically, an SNR of 51 dB and an SFDR of almost –90 dBFS are realized by this configuration. Figure 6 shows an FFT of the AD8369 delivering a single tone at –1 dBFS (that is, 2 V p-p) at the input of the ADC with an HD2 of –83 dBc and HD3 of –80 dBc. Figure 7 shows that the two-tone, third-order intermodulation distortion level is –65.5 dBc. 0 –10 70MHz – 1dBFS HD2 = –83dBc HD3 = –80dBc SNR = 51dB –20 POUT – dBFS –30 –40 –50 –60 PCB Layout Considerations –70 –80 –90 –100 0 5 10 15 20 25 ADC OUTPUT FREQUENCY – MHz 30 Figure 6. Single-Tone 70 MHz, –1 dBFS Each input and output pin of the AD8369 presents 100 W relative to their respective ac grounds. To ensure that signal integrity is not seriously impaired by the printed circuit board, the relevant connection traces should provide a characteristic impedance of 100 W to the ground plane. This can be achieved through proper layout. Figure 8 shows the cross section of a PC board and Table II shows the dimensions that will provide a 100 W line impedance. 0 Table II. Dimensions Required for 100 W Characteristic Impedance Microstrip Line in FR-4 –7dBFS –10 –20 r (FR-4) POUT – dBFS –30 W H T –40 –50 4.6 22 mils 53 mils 2.1 mils –60 –72.5dBFS –70 –80 –90 –100 0 5 10 15 20 25 ADC OUTPUT FREQUENCY – MHz 30 Figure 7. Two-Tone, 70 MHz, 70.3 MHz, –7 dBFS –16– REV. 0 AD8369 Key considerations when laying out an RF trace with a controlled impedance include: • • 3W • Keep the length of the input and output connection lines as short as possible. SW 2 3 1 PWUP ⑀r H Ensure that the width of the microstrip line is constant and that there are as few discontinuations (component pads, etc.) as possible along the length of the line. Width variations cause impedance discontinuities in the line and may result in unwanted reflections. Do not use silkscreen over the signal line; this will alter the line impedance. 3W T Space the ground plane to either side of the signal trace at least 3 line-widths away to ensure that a microstrip (vertical dielectric) line is formed, rather than a coplanar (lateral dielectric) waveguide. • W Figure 8. Cross-Sectional View of a PC Board The AD8369 contains both digital and analog sections. Care should be taken to ensure that the digital and analog sections are adequately isolated on the PC board. The use of separate ground planes for each section connected at only one point via a ferrite bead inductor will ensure that the digital pulses do not adversely affect the analog section of the AD8369. PWDN R5 OPEN 2 VS C5 0.1F C7 C8 0.1F 1nF C8 1nF C2 C4 1nF 16 15 14 13 12 11 INHI COMM PWUP VPOS SENB INⴙ J1 10 9 1nF FILT CMDC OPHI T1 R2 0⍀ TC4-1W INⴚ J2 R11 0⍀ R1 0⍀ RL TC4-1W AD8369 INLO COMM BIT0 1nF OUTⴙ J6 T2 1 2 BIT1 BIT2 4 5 3 C3 R6 0⍀ R7 0⍀ R12 0⍀ BIT3 DENB OPLO 6 R8 0⍀ 7 R9 0⍀ 8 OUTⴚ J7 1nF C1 R10 0⍀ LATCH CLOCK DATA C9 OPEN VS R3 1k⍀ R13 1k⍀ 2 R4 1k⍀ 1 5 3 4 6 8 11 SW3 7 9 10 4 SW4 VS 12 1 2 4 8 A 2 3 SW1 B 1 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 D-SUB 25 PIN MALE Figure 9. Evaluation Board Schematic REV. 0 –17– AD8369 Evaluation Board Evaluation Board Software The evaluation board allows for quick testing of the AD8369 using standard 50 W test equipment. The schematic is shown in Figure 9. Transformers T1 and T2 are used to transform 50 W source and load impedances to the desired 200 W reference level. This allows for broadband operation of the device without the need to pay close attention to impedance matching (see Table III). The evaluation board comes with the AD8369 control software that allows for serial gain control from most computers. The evaluation board is connected via a cable to the parallel port of the computer. By simply adjusting the slider bar in the control software, the gain code is automatically updated to the AD8369. On some older PCs, it may be necessary to use 5 kW pull-up resistors to VPOS on DATA, CLOCK, and LATCH depending upon the capabilities of the port transceiver. It is necessary to set SW3 on the evaluation board to “SER” for the control software to function normally. A screen shot of the evaluation software interface is shown in Figure 11. Figure 10. Evaluation Board Layout Figure 11. Evaluation Software Interface –18– REV. 0 AD8369 Table III. AD8369 Evaluation Board Configuration Options Component Function Default Condition VPOS, GND Supply and Ground Vector Pins Not Applicable SW1 Data Enable: Set to Position A when in serial mode of operation, set to Position B when in parallel mode of operation. Not Applicable SW2 Device Enable: When in the PWDN position, the PWUP pin will be connected to ground and the AD8369 will be disabled. The device is enabled when the switch is in the PWUP position, connecting the PWUP pin to VPOS. Not Applicable SW3, R5 Serial/Parallel Selection. The device will respond to serial control inputs from connector P1 when the switch is in the SER position. Parallel operation is achieved when in the PAR position. Device can be hardwired for parallel mode of operation by placing the 0 W resistor in position R5. Not Applicable R5 = Open (Size 0603) SW4 Parallel Interface Control. Used to hardwire BIT0 through BIT3 to the desired gain code when in parallel mode of operation. The switch functions as a hexadecimal to binary encoder (Gain Code 0 = 0000, Gain Code 15 = 1111). Not Applicable J1, J2, J6, J7 Input and Output Signal Connectors. These SMA connectors provide a convenient way to interface the evaluation board with 50 W test equipment. Not Applicable C1, C2, C3, C4 AC-Coupling Capacitors. Provides ac-coupling of the input and output signals. C1, C2, C3, C4 = 1 nF (Size 0603) T1, T2 Impedance Transformers. Used to transform the 200 W input and output impedance to 50 W. T1, T2 = TC4-1W (MiniCircuits) R1, R2, R11, R12 Single-Ended or Differential. R2 and R11 are used to ground the center tap of the secondary windings on transformers T1 and T2. R1 and R12 should be used to ground J2 and J7 when used in single-ended applications. R1 and R12 should be removed for differential operation. R1, R2, R11, R12 = 0 W (Size 0603) R6, R7, R8, R9, R10 Control Interface Resistors. Simple series resistors for each control interface signal. R6, R7, R8, R9, R10 = 0 W (Size 0603) C5, C6, C8 Power Supply Decoupling. Nominal supply decoupling consists of a 0.1 mF capacitor to ground followed by a 1 nF capacitor to ground positioned as close to the device as possible. C8 provides additional decoupling of the input common-mode voltage. C5 = 0.1 mF (Size 0603) C6 = C8 = 1 nF (Size 0603) C7 High-Pass Filter Capacitor. Used to set high-pass corner frequency of output. C7 = 0.1 mF (Size 0603) C9 Clock Filter Capacitor. May be required with some printer ports to minimize overshoot. The clock waveform may be smoothed using a simple filter network established by R7 and C9. Some experimentation may be necessary to determine optimum values. C9 = Open (Size 0603) REV. 0 –19– AD8369 APPENDIX Characterization Equipment Composite Waveform Assumption The nonlinear two-tone measurements made for this data sheet, i.e., IMD3 and IP3, are based on the assumption of a fixed value composite waveform at the output, generally 1 V p-p. The frequencies of interest dictate the use of RF test equipment and because this equipment is generally not designed to work in units of volts, but rather watts and dBm, an assumption was made to simplify equipment setup and operation. Two sets of automated characterization equipment were used to obtain the majority of the information contained in this data sheet. An Agilent N4441A Balanced Measurement System was used to obtain the gain, phase, group delay, reverse isolation, CMRR, and s-parameter information. Except for the s-parameter information, T-attenuator pads were used to match the 50 W impedance of the ports of this instrument to the AD8369. Two sinusoidal tones can be represented as: V1 = sin (2p f1 t ) An Anritsu MS4623B “Scorpion” Vector Network Analyzer was used to obtain nonlinear measurements IMD3, IP3, and P1dB through matching baluns and attenuator networks. V2 = sin (2p f2 t ) The average voltage of one tone is: Definitions of Selected Parameters Common-mode rejection ratio (TPC 14) has been defined for this characterization effort as: 1T 1 2 Ú (V1 ) dt = T0 2 Differential - Mode, forwardgain Common - Mode, forwardgain where T is the period of the waveform. The average voltage of the two-tone composite signal is: where the numerator is the gain into a differential load at the output due to a differential source at the input and the denominator is the gain into a common-mode load at the output due to a common-mode source at the input. In terms of mixed-mode s-parameters, this equates to: SDD 21 SCC 21 1T 2 Ú (V1 + V2 ) dt = 1 T0 So each tone contributes 1/÷2 to the average composite amplitude in terms of voltage. It can be shown that the average power of this composite waveform is two times greater, or 3dB, than that of the single tone. This principle can be used to set correct input amplitudes from generators scaled in dBm and is correct if the two tones are of equal amplitude and are not farther than 1 percent apart in frequency. Reverse isolation (TPC 17) is defined as SDD12. More information on mixed-mode s-parameters can be obtained in the a reference by Bockelman, D.E. and Eisenstadt, W.R., Combined Differential and Common-Mode Scattering Parameters: Theory and Simulation. IEEE Transactions on Microwave Theory and Techniques, v 43, n 7, 1530 (July 1995). VS 0.1F 69.8⍀ 69.8⍀ 10nF 10nF 16 15 0.1F 14 13 12 11 INHI COMM PWUP VPOS SENB RL 69.8⍀ 69.8⍀ 10 9 10nF R1 R2 10nF R1 R2 FILT CMDC OPHI AD8369 INLO COMM BIT0 1 RL= 200⍀ DIFFERENTIAL: R1 = 69.8⍀, R2 = 69.8⍀ RL= 1000⍀ DIFFERENTIAL: R1 = 475⍀, R2 = 52.3⍀ 1nF 2 3 BIT1 BIT2 4 5 BIT3 DENB OPLO 6 7 10nF 8 CONTROL INTERFACE PORT1 AGILENT N4441A (ALL PORTS 50⍀) PORT3 PORT2 PORT4 Figure 12. Balanced Measurement System Setup –20– REV. 0 AD8369 VS 0.1F 10nF 10nF 16 0.1F 15 14 13 12 1nF 11 INHI COMM PWUP VPOS SENB 10 9 10nF FILT CMDC OPHI MINI-CIRCUITS TC4-1W MINI-CIRCUITS TC4-1W RL AD8369 INLO COMM BIT0 1 2 BIT1 BIT2 4 5 3 BIT3 DENB OPLO 6 7 8 10nF 10nF CONTROL INTERFACE ANRITSU MS4623B VNA SOURCE OUTPUT RECEIVER INPUT Figure 13. Vector Network Analyzer Setup (200 W) VS 0.1F 10nF 16 10nF 15 0.1F 14 13 12 INHI COMM PWUP VPOS SENB 1nF 11 10 9 10nF 604⍀ FILT CMDC OPHI MINI-CIRCUITS TC4-1W MINI-CIRCUITS TC4-1W 4120⍀ AD8369 INLO COMM BIT0 1 2 3 BIT1 BIT2 4 5 237⍀ BIT3 DENB OPLO 6 7 8 10nF 10nF 604⍀ CONTROL INTERFACE ANRITSU MS4623B VNA SOURCE OUTPUT RECEIVER INPUT Figure 14. Vector Network Analyzer Setup (1 kW) REV. 0 –21– AD8369 VS 5.0V 0.1F 1nF 0.1F 100nF 100nF 16 15 14 13 12 1nF 11 INHI COMM PWUP VPOS SENB 10 9 100nF FILT CMDC OPHI –19dB 100nF 162⍀ 113⍀ AD8351 MACOM ETC1-1-13 LPF 191⍀ RL AD8369 113⍀ 191⍀ 100nF 162⍀ 100nF INLO COMM BIT0 1 2 3 BIT1 BIT2 4 5 TEK P6248 DIFF PROBE BIT3 DENB OPLO 6 7 8 –12dB 100nF 100nF VS RF OUT TEK 1103 PROBE POWER SUPPLY R & S SMT-03 SIGNAL GENERATOR R&S FSEA30 SPECTRUM ANALYZER Figure 15. Harmonic Distortion Setup R & S SMT-03 SIGNAL GENERATOR VS 5.0V 0.1F 1nF 0.1F RF OUT 1nF –34dBm AT 70MHz 10nF 16 15 14 13 12 11 INHI COMM PWUP VPOS SENB MINI-CIRCUITS TC4-1W RL 9 2 3 10nF BIT1 BIT2 4 5 604⍀ AGILENT INFINIUM DSO 4120⍀ AD8369 INLO COMM BIT0 1 10 FILT CMDC OPHI 237⍀ MINI-CIRCUITS TC4-1W BIT3 DENB OPLO 6 7 8 10nF 10nF 604⍀ 50⍀ PICOSECOND PULSE LABS PULSE GENERATOR VS Figure 16. Gain Step Response Setup –22– REV. 0 AD8369 AGILENT 8112A PULSE GENERATOR SPLITTER TEK TDS 5104 DSO 2F VS 5.0V 10F R & S SMT-03 SIGNAL GENERATOR RF OUT PULSE IN 0.1F 10nF 16 15 14 13 12 INHI COMM PWUP VPOS SENB MINI-CIRCUITS TC4-1W 1nF 11 10 100nF 9 FILT CMDC OPHI 1000⍀ AD8369 0⍀ TEK 1103 PROBE POWER SUPPLY TEK P6248 DIFF PROBE 0⍀ INLO COMM BIT0 1 10nF 2 3 BIT1 BIT2 4 5 BIT3 DENB OPLO 6 7 8 C2 100nF VS Figure 17. Pulse Response Setup R & S SMT-03 SIGNAL GENERATOR VS 5.0V 0.1F 1nF 1nF 0.1F RF OUT –20dBm AT 10MHz 10nF 16 15 14 13 12 11 INHI COMM PWUP VPOS SENB MINI-CIRCUITS TC4-1W RL 2 3 10nF BIT1 BIT2 4 5 237⍀ BIT3 DENB OPLO 6 7 8 10nF VS 50⍀ Figure 18. Overdrive Response Setup REV. 0 604⍀ AGILENT INFINIUM DSO 4120⍀ 10nF PICOSECOND PULSE LABS PULSE GENERATOR 9 AD8369 INLO COMM BIT0 1 10 FILT CMDC OPHI –23– 604⍀ MINI-CIRCUITS TC4-1W AD8369 OUTLINE DIMENSIONS 16-Lead Thin Shrink Small Outline Package [TSSOP] (RU-16) Dimensions shown in millimeters 16 C03029–0–11/02(0) 5.10 5.00 4.90 9 4.50 4.40 4.30 6.40 BSC 1 8 PIN 1 1.20 MAX 0.15 0.05 0.20 0.09 COPLANARITY 0.10 SEATING PLANE 8ⴗ 0ⴗ 0.75 0.60 0.45 COMPLIANT TO JEDEC STANDARDS MO-153AB PRINTED IN U.S.A. 0.65 BSC 0.30 0.19 –24– REV. 0