OPA OPA OPA OPA OPA OPA OPA OPA OPA TM µ Ω ± ± ± ± + OPA OPA OPA Offset Trim Offset Trim Out A V+ Out A Out D In +In V+ Output In A +In A A B Out B In B In A +In A A D In D +In D V NC V +In B V+ V +In B In B B C 9 +In C In C Out B Out C PDSJ-9C November, 99
± G =, f = khz V O = Vrms R L = kω. % R L = Ω. % G =, f = khz V O = Vp-p 9 db THD <.%, R L = kω, V S = ±V. dbu MHz ± ± V/µs. MHz.% G = V C L = pf. µs.% G = V C L = pf µs (V IN ) ( ) = V S. µs f = Hz khz. µvrms f = khz nv/ Hz f = khz fa/ Hz ±. ± mv T A = C + C ± ± () mv T A = C + C ± µv/ C (PSRR) V S = ±.V ±V 9 db dc, R L = kω db f = khz, R L = kω db () V CM =V + ± pa () ± na () V CM =V ± ± pa (V )+. ± (V+). V V CM =.V +.V db T A = C + C 9 db Ω pf V CM =.V +.V Ω pf R L = kω V O =.V +.V db R L = kω V O =.V +.V db R L = Ω V O =.V +.V db R L = kω (V )+. (V+). V R L = kω (V )+. (V+). V R L = Ω (V )+. (V+). V ± ma () f = khz. Ω f = khz Ω ± ma ± V ±. ± V I O = ma + C + C + C θ JA DIP C/W C/W DIP C/W C/W
OPAPA C + C OPAUA C + C OPAPA C + C OPAUA C + C OPAPA C + C OPAUA C + C ± Ω.. TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY R L kω Ω SMPTE INTERMODULATION DISTORTION vs OUTPUT AMPLITUDE G = + f = khz R L = kω THD+Noise (%). G = +. G = + V O = Vrms. k k k IMD (%). OPA OP. OPA Baseline.. m. Output Amplitude (Vpp)
± Ω. TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY V O = Vrms R L = kω HEADROOM TOTAL HARMONIC DISTORTION + NOISE vs OUTPUT AMPLITUDE V S = ±V R L = kω f = khz THD <.% OPA.Vrms OP.Vrms THD+Noise (%).. V S = ± THD+Noise (%).. OPA OP OPA V S = ± V S = ±. k k k. Baseline.. Output Amplitude (Vrms) Amplitude (% of Fundamentals).... HARMONIC DISTORTION + NOISE vs FREQUENCY nd Harmonic rd Harmonic V O = Vrms. k k k R L = Ω R L = kω Voltage Noise (nv/ Hz) k VOLTAGE NOISE vs SOURCE RESISTANCE OP+ Resistor OPA+ Resistor Resistor Noise Only V n (total) = (i n R S ) + e n + ktr S. k k k M M Source Resistance (Ω) k INPUT VOLTAGE AND CURRENT NOISE SPECTRAL DENSITY vs FREQUENCY INPUT-REFERRED NOISE VOLTAGE vs NOISE BANDWIDTH R S = Ω Voltage Noise (nv/ Hz) Current Noise (fa/ Hz) Voltage Noise Noise Voltage (µv) Peak-to-Peak RMS Current Noise k k k M. k k k Noise Bandwidth (Hz)
± Ω Voltage Gain (db) OPEN-LOOP GAIN/PHASE vs FREQUENCY φ 9 G. k k k M M Phase Shift ( ) Closed-Loop Gain (db) G = + G = + G = + CLOSED-LOOP GAIN vs FREQUENCY k k k M M PSR, CMR (db) POWER SUPPLY AND COMMON-MODE REJECTION vs FREQUENCY +PSR k k k M PSR CMR Channel Separation (db) CHANNEL SEPARATION vs FREQUENCY Dual and quad devices. G =, all channels. Quad measured channel A to D or B to C other combinations yield improved rejection. k k k R L = kω R L = Output Voltage (Vp-p) V S = ±V V S = ±V MAXIMUM OUTPUT VOLTAGE vs FREQUENCY V S = ±.V k k M M Maximum output voltage without slew-rate induced distortion Closed-Loop Output Impedance (Ω)... CLOSED-LOOP OUTPUT IMPEDANCE vs FREQUENCY Note: Open-Loop Output Impedance at f = khz is Ω G = + G = + G = + G = +. k k k
± Ω Input Bias Current (pa) k k k INPUT BIAS CURRENT vs TEMPERATURE High Speed Test Warmed Up Dual Single. Ambient Temperature ( C) Input Bias Current (pa) 9 INPUT BIAS CURRENT vs INPUT COMMON-MODE VOLTAGE High Speed Test Common-Mode Voltage (V) OPEN-LOOP GAIN vs TEMPERATURE CMR, PSR vs TEMPERATURE Open-Loop Gain (db) R L = kω R L = kω R L = Ω FPO CMR, PSR (db) CMR PSR Temperature ( C) 9 Ambient Temperature ( C) Quiescent Current Per Amp (ma) QUIESCENT CURRENT AND SHORT-CIRCUIT CURRENT vs TEMPERATURE... ±I SC. ±I Q.9. Ambient Temperature ( C) Short-Circuit Current (ma) Output Voltage Swing (V) OUTPUT VOLTAGE SWING vs OUTPUT CURRENT V IN = V V IN = V C C C C C C C C Output Current (ma)
± Ω Percent of Amplifiers (%) OFFSET VOLTAGE PRODUCTION DISTRIBUTION Typical production distribution of packaged units. Single and dual units included. SMALL-SIGNAL STEP RESPONSE G =, C L = pf LARGE-SIGNAL STEP RESPONSE G =, C L = pf mv/div V/div Percent of Amplifiers (%) OFFSET VOLTAGE DRIFT PRODUCTION DISTRIBUTION Typical production distribution of packaged units. Single and dual units included. Offset Voltage (V)......... 9. Offset Voltage Drift (µv/ C)... ns/div µs/div SETTLING TIME vs CLOSED-LOOP GAIN SMALL-SIGNAL OVERSHOOT vs LOAD CAPACITANCE G = + Settling Time (µs).%.% Overshoot (%) G = G = ±. ± ± ± ± Closed-Loop Gain (V/V) pf nf nf Load Capacitance
± ± ± Ω V+ ± Trim Range: ±mv typ nf kω OPA OPA single op amp only. nf Use offset adjust pins only to null offset voltage of op amp see text. V Ω R R SIG. GAIN DIST. GAIN R R R kω Ω R Signal Gain = + R R OPA V O = Vrms Ω Ω kω kω Ω R Distortion Gain = + R II R Generator Output Analyzer Input Audio Precision System One Analyzer () R L kω IBM PC or Compatible NOTE: () Measurement BW = khz
Ω Ω Ω V ( total) = ( i R ) + e + ktr S n n S n s Ω Ω Ω± ± R R OPA V OUT V IN If R S > kω or R II R > kω R S = R II R 9
INCHES MILLIMETERS DIM MIN MAX MIN MAX A.. A.. A..9.9.9 b.... b.... b.... c.... D.. 9.. D.. E.... E.... e. BASIC. BASIC ea. BASIC. BASIC eb..9 ec.... L...9. N INCHES MILLIMETERS DIM MIN MAX MIN MAX A.. A.. A..9.9.9 b.... b.... c.... D... 9.9 D.. E.... E.... e. BASIC. BASIC ea. BASIC. BASIC eb..9 ec.... L...9. N
INCHES MILLIMETERS DIM MIN MAX MIN MAX A.... A..9.. B.... C..9.. D.9.9..9 E.9... e. BASIC. BASIC H.... h.99.9.. L.... N INCHES MILLIMETERS DIM MIN MAX MIN MAX A.... A..9.. B.... C..9.9. D.... E.9... e. BASIC. BASIC H.... h.99.9.. L.... N