130 MHz Current Feedback Amplifier Features General Description # 130 MHz 3 dB bandwidth (AV e a 2) # 180 MHz 3 dB bandwidth (AV e a 1) # 0.01% differential gain, RL e 500X # 0.01 differential phase, RL e 500X # Low supply current, 8.5 mA # Wide supply range, g 2V to g 15V # 80 mA output current (peak) # Low cost # 1500 V/ms slew rate # Input common mode range to within 1.5V of supplies # 35 ns settling time to 0.1% The EL2160C is a current feedback operational amplifier with b 3 dB bandwidth of 130 MHz at a gain of a 2. Built using the Elantec proprietary monolithic complementary bipolar process, this amplifer uses current mode feedback to achieve more bandwidth at a given gain than a conventional voltage feedback operational amplifier. Applications # # # # # Video amplifiers Cable drivers RGB amplifiers Test equipment amplifiers Current to voltage converter EL2160C EL2160C The EL2160C is designed to drive a double terminated 75X coax cable to video levels. Differential gain and phase are excellent when driving both loads of 500X ( k 0.01%/ k 0.01 ) and double terminated 75X cables (0.025%/0.1 ). The amplifier can operate on any supply voltage from 4V ( g 2V) to 33V ( g 16.5V), yet consume only 8.5 mA at any supply voltage. Using industry standard pinouts, the EL2160C is available in 8-pin P-DIP and 8-pin SO packages. For dual and quad applications, please see the EL2260C/EL2460C datasheet. Elantec's facilities comply with MIL-I-45208A and offer applicable quality specifications. See the Elantec document, QRA-2: Elantec's Military ProcessingMonolithic Products. Connection Diagram EL2160C SO, P-DIP Packages Ordering Information Part No. Temp. Range Package OutlineY EL2160CN b 40 C to a 85 C 8-Pin P-DIP MDP0031 EL2160CS b 40 C to a 85 C 8-Pin SOIC MDP0027 2060 - 1 Top View December 1995 Rev B Note: All information contained in this data sheet has been carefully checked and is believed to be accurate as of the date of publication; however, this data sheet cannot be a ``controlled document''. Current revisions, if any, to these specifications are maintained at the factory and are available upon your request. We recommend checking the revision level before finalization of your design documentation. (c) 1993 Elantec, Inc. EL2160C 130 MHz Current Feedback Amplifier Absolute Maximum Ratings (TA e 25 C) Voltage between VS a and VSb Voltage between a IN and bIN Current into a IN or bIN Internal Power Dissipation Operating Ambient Temperature Range Operating Junction Temperature Plastic Packages Output Current Storage Temperature Range a 33V g 6V 10 mA See Curves b 40 C to a 85 C 150 C g 50 mA b 65 C to a 150 C Important Note: All parameters having Min/Max specifications are guaranteed. The Test Level column indicates the specific device testing actually performed during production and Quality inspection. Elantec performs most electrical tests using modern high-speed automatic test equipment, specifically the LTX77 Series system. Unless otherwise noted, all tests are pulsed tests, therefore TJ e TC e TA. Test Level I II III IV V Test Procedure 100% production tested and QA sample tested per QA test plan QCX0002. 100% production tested at TA e 25 C and QA sample tested at TA e 25 C , TMAX and TMIN per QA test plan QCX0002. QA sample tested per QA test plan QCX0002. Parameter is guaranteed (but not tested) by Design and Characterization Data. Parameter is typical value at TA e 25 C for information purposes only. Open Loop DC Electrical Characteristics VS e g 15V, RL e 150X, TA e 25 C unless otherwise specified Description Conditions Limits Temp Min VS e g 5V, g 15V Test Level Units Typ Max EL2160C 25 C 2 10 I mV Full 10 V mV/ C VOS Input Offset Voltage TC VOS Average Offset Voltage Drift (Note 1) a IIN a Input Current VS e g 5V, g 15V 25 C 0.5 5 I mA b IIN b Input Current VS e g 5V, g 15V 25 C 5 25 I mA CMRR Common Mode Rejection Ratio (Note 2) VS e g 5V, g 15V II dB b ICMR b Input Current Common Mode Rejection (Note 2) VS e g 5V, g 15V I mA/V PSRR Power Supply Rejection Ratio (Note 3) 25 C II dB b IPSR b Input Current Power Supply Rejection (Note 3) 25 C I mA/V 2 25 C 50 25 C 55 0.2 75 5 95 0.2 5 TD is 2.5in Parameter EL2160C 130 MHz Current Feedback Amplifier Open Loop DC Electrical Characteristics Contd. VS e g 15V, RL e 150X, TA e 25 C unless otherwise specified ROL Description Transimpedance (Note 4) Conditions Limits Temp Min Typ Test Level Max Units EL2160C VS e g 15V RL e 400X 25 C 500 2000 I kX VS e g 5V RL e 150X 25 C 500 1800 I kX 1.5 a RIN a Input Resistance 25 C 3.0 II MX a CIN a Input Capacitance 25 C 2.5 V pF VS e g 15V 25 C g 13.5 V V VS e g 5V 25 C g 3.5 V V RL e 400X, VS e g 15V 25 C g 13.5 I V RL e 150X, VS e g 15V 25 C g 12 V V RL e 150X, VS e g 5V 25 C g 3.0 g 3.7 I V 60 100 150 I mA CMIR VO Common Mode Input Range Output Voltage Swing g 12 ISC Output Short Circuit Current (Note 5) VS e g 5V, VS e g 15V 25 C IS Supply Current VS e g 15V 25 C 8.5 12.0 I mA VS e g 5V 25 C 6.4 9.5 I mA 3 TD is 3.4in Parameter EL2160C 130 MHz Current Feedback Amplifier Closed Loop AC Electrical Characteristics VS e g 15V, AV e a 2, RF e 560X, RL e 150X, TA e 25 C unless otherwise noted Description Limits Conditions Min BW b 3 dB Bandwidth (Note 8) Slew Rate (Notes 6, 8) Test Level Max Units EL2160C VS e g 15V, AV e a 2 130 V MHz VS e g 15V, AV e a 1 180 V MHz VS e g 5V, AV e a 2 100 V MHz VS e g 5V, AV e a 1 SR Typ RL e 400X 1000 RF e 1KX, RG e 110X RL e 400X V MHz IV V/ms 1500 V V/ms 2.7 V ns 3.2 V ns tr, tf Rise Time, Fall Time, (Note 8) tpd Propagation Delay (Note 8) OS Overshoot (Note 8) VOUT e g 500 mV 0 V % ts 0.1% Settling Time (Note 8) VOUT e g 10V AV e b1, RL e 1K 35 V ns dG Differential Gain (Notes 7, 8) RL e 150X 0.025 V % RL e 500X 0.006 V % Differential Phase RL e 150X 0.1 V deg ( ) (Notes 7, 8) RL e 500X 0.005 V deg ( ) dP VOUT e g 500mV 110 1500 Note 1: Measured from TMIN to TMAX. Note 2: VCM e g 10V for VS e g 15V and TA e 25 C VCM e g 3V for VS e g 5V and TA e 25 C Note 3: The supplies are moved from g 2.5V to g 15V. Note 4: VOUT e g 7V for VS e g 15V, and VOUT e g 2V for VS e g 5V. Note 5: A heat sink is required to keep junction temperature below absolute maximum when an output is shorted. Note 6: Slew Rate is with VOUT from a 10V to b10V and measured at the 25% and 75% points. Note 7: DC offset from b0.714V through a 0.714V, AC amplitude 286 mVp-p, f e 3.58 MHz. Note 8: All AC tests are performed on a ``warmed up'' part, except for Slew Rate, which is pulse tested. 4 TD is 3.5in Parameter EL2160C 130 MHz Current Feedback Amplifier Typical Performance Curves Non-Inverting Frequency Response (Gain) Inverting Frequency Response (Gain) 3 dB Bandwidth vs Supply Voltage for AV e b 1 Non-Inverting Frequency Response (Phase) Inverting Frequency Response (Phase) Peaking vs Supply Voltage for AV e b 1 Frequency Response for Various RL Frequency Response for Various RF and RG 3 dB Bandwidth vs Temperature for AV e b 1 2060 - 2 5 EL2160C 130 MHz Current Feedback Amplifier Typical Performance Curves Contd. 3 dB Bandwidth vs Supply Voltage for AV e a 1 Peaking vs Supply Voltage for AV e a 1 3 dB Bandwidth vs Temperature for AV e a 1 3 dB Bandwidth vs Supply Voltage for AV e a 2 Peaking vs Supply Voltage for AV e a 2 3 dB Bandwidth vs Temperature for AV e a 2 3 dB Bandwidth vs Supply Voltage for AV e a 10 Peaking vs Supply Voltage for AV e a 10 3 dB Bandwidth vs Temperature for AV e a 10 2060 - 3 6 EL2160C 130 MHz Current Feedback Amplifier Typical Performance Curves Contd. Frequency Response for Various CL Frequency Response for Various CIN b PSRR and CMRR vs Frequency 2nd and 3rd Harmonic Distortion vs Frequency Transimpedance (ROL) vs Frequency Voltage and Current Noise vs Frequency Transimpedance (ROL) vs Die Temperature Closed-Loop Output Impedance vs Frequency 2060 - 4 7 EL2160C 130 MHz Current Feedback Amplifier Typical Performance Curves Contd. Offset Voltage vs Die Temperature (4 Samples) Supply Current vs Die Temperature Supply Current vs Supply Voltage a Input Resistance vs Die Temperature Input Current vs Die Temperature a Input Bias Current vs Input Voltage Output Voltage Swing vs Die Temperature Short Circuit Current vs Die Temperature PSRR & CMRR vs Die Temperature 2060 - 5 8 EL2160C 130 MHz Current Feedback Amplifier Typical Performance Curves Contd. Differential Gain vs DC Input Voltage, RL e 150 Differential Phase vs DC Input Voltage, RL e 150 Small Signal Pulse Response Differential Gain vs DC Input Voltage, RL e 500 Differential Phase vs DC Input Voltage, RL e 500 Large Signal Pulse Response Slew Rate vs Supply Voltage Slew Rate vs Temperature Settling Time vs Settling Accuracy 2060 - 6 9 EL2160C 130 MHz Current Feedback Amplifier Typical Performance Curves Contd. Long Term Settling Error 8-Lead Plastic DIP Maximum Power Dissipation vs Ambient Temperature 8-Lead Plastic SO Maximum Power Dissipation vs Ambient Temperature 2060 - 7 Burn-In Circuit EL2160C 2060 - 8 10 EL2160C 130 MHz Current Feedback Amplifier Differential Gain and Phase Test Circuit 2060 - 9 Simplified Schematic (One Amplifier) 2060 - 10 11 EL2160C 130 MHz Current Feedback Amplifier Capacitance at the Inverting Input Applications Information Due to the topology of the current feedback amplifier, stray capacitance at the inverting input will affect the AC and transient performance of the EL2160C when operating in the noninverting configuration. The characteristic curve of gain vs. frequency with variations of CIN b emphasizes this effect. The curve illustrates how the bandwidth can be extended to beyond 200 MHz with some additional peaking with an additional 2 pF of capacitance at the VIN b pin for the case of AV e a 2. Higher values of capacitance will be required to obtain similar effects at higher gains. Product Description The EL2160C is a current mode feedback amplifier that offers wide bandwidth and good video specifications at a moderately low supply current. It is built using Elantec's proprietary complimentary bipolar process and is offered in industry standard pin-outs. Due to the current feedback architecture, the EL2160C closed-loop 3 dB bandwidth is dependent on the value of the feedback resistor. First the desired bandwidth is selected by choosing the feedback resistor, RF, and then the gain is set by picking the gain resistor, RG. The curves at the beginning of the Typical Performance Curves section show the effect of varying both RF and RG. The 3 dB bandwidth is somewhat dependent on the power supply voltage. As the supply voltage is decreased, internal junction capacitances increase, causing a reduction in closed loop bandwidth. To compensate for this, smaller values of feedback resistor can be used at lower supply voltages. In the inverting gain mode, added capacitance at the inverting input has little effect since this point is at a virtual ground and stray capacitance is therefore not ``seen'' by the amplifier. Feedback Resistor Values The EL2160C has been designed and specified with RF e 560X for AV e a 2. This value of feedback resistor yields extremely flat frequency response with little to no peaking out to 130 MHz. As is the case with all current feedback amplifiers, wider bandwidth, at the expense of slight peaking, can be obtained by reducing the value of the feedback resistor. Inversely, larger values of feedback resistor will cause rolloff to occur at a lower frequency. By reducing RF to 430X, bandwidth can be extended to 170 MHz with under 1 dB of peaking. Further reduction of RF to 360X increases the bandwidth to 195 MHz with about 2.5 dB of peaking. See the curves in the Typical Performance Curves section which show 3 dB bandwidth and peaking vs. frequency for various feedback resistors and various supply voltages. Power Supply Bypassing and Printed Circuit Board Layout As with any high frequency device, good printed circuit board layout is necessary for optimum performance. Ground plane construction is highly recommended. Lead lengths should be as short as possible, below (/4x . The power supply pins must be well bypassed to reduce the risk of oscillation. A 1.0 mF tantalum capacitor in parallel with a 0.01 mF ceramic capacitor is adequate for each supply pin. For good AC performance, parasitic capacitances should be kept to a minimum, especially at the inverting input (see Capacitance at the Inverting Input section). This implies keeping the ground plane away from this pin. Carbon resistors are acceptable, while use of wire-wound resistors should not be used because of their parasitic inductance. Similarly, capacitors should be low inductance for best performance. Use of sockets, particularly for the SO package, should be avoided. Sockets add parasitic inductance and capacitance which will result in peaking and overshoot. Bandwidth vs Temperature Whereas many amplifier's supply current and consequently 3 dB bandwidth drop off at high temperature, the EL2160C was designed to have little supply current variations with temperature. An immediate benefit from this is that the 3 dB bandwidth does not drop off drastically with temperature. With VS e g 15V and AV e a 2, the bandwidth only varies from 150 MHz to 110 MHz over the entire die junction temperature range of 0 C k T k 150 C. 12 EL2160C 130 MHz Current Feedback Amplifier about 40 ms. This is a thermal settling error caused by a power dissipation differential (before and after the voltage step). For AV e b 1, due to the inverting mode configuration, this tail does not appear since the input stage does not experience the large voltage change as in the noninverting mode. With AV e b 1, 0.01% settling time is slightly greater than 100 ns. Applications Information Contd. Supply Voltage Range The EL2160C has been designed to operate with supply voltages from g 2V to g 15V. Optimum bandwidth, slew rate, and video characteristics are obtained at higher supply voltages. However, at g 2V supplies, the 3 dB bandwidth at AV e a 2 is a respectable 70 MHz. The following figure is an oscilloscope plot of the EL2160C at g 2V supplies, AV e a 2, RF e RG e 560X, driving a load of 150X, showing a clean g 600 mV signal at the output. Power Dissipation The EL2160C amplifier combines both high speed and large output current drive capability at a moderate supply current in very small packages. It is possible to exceed the maximum junction temperature allowed under certain supply voltage, temperature, and loading conditions. To ensure that the EL2160C remains within its absolute maximum ratings, the following discussion will help to avoid exceeding the maximum junction temperature. The maximum power dissipation allowed in a package is determined by its thermal resistance and the amount of temperature rise according to 2060 - 11 PDMAX e If a single supply is desired, values from a 4V to a 30V can be used as long as the input common mode range is not exceeded. When using a single supply, be sure to either 1) DC bias the inputs at an appropriate common mode voltage and AC couple the signal, or 2) ensure the driving signal is within the common mode range of the EL2160C. TJMAX b TAMAX iJA The maximum power dissipation actually produced by an IC is the total quiescent supply current times the total power supply voltage plus the power in the IC due to the load, or VOUT PDMAX e 2 * VS * IS a (VS b VOUT)* RL Settling Characteristics where IS is the supply current. (To be more accurate, the quiescent supply current flowing in the output driver transistor should be subtracted from the first term because, under loading and due to the class AB nature of the output stage, the output driver current is now included in the second term.) The EL2160C offers superb settling characteristics to 0.1%, typically in the 35 ns to 40 ns range. There are no aberrations created from the input stage which often cause longer settling times in other current feedback amplifiers. The EL2160C is not slew rate limited, therefore any size step up to g 10V gives approximately the same settling time. In general, an amplifier's AC performance degrades at higher operating temperature and lower supply current. Unlike some amplifiers, the EL2160C maintains almost constant supply As can be seen from the Long Term Settling Error curve, for AV e a 1, there is approximately a 0.035% residual which tails away to 0.01% in 13 EL2160C 130 MHz Current Feedback Amplifier Applications Information Contd. Supply Voltage vs RLOAD for Various VOUT (PDIP Package) current over temperature so that AC performance is not degraded as much over the entire operating temperature range. Of course, this increase in performance doesn't come for free. Since the current has increased, supply voltages must be limited so that maximum power ratings are not exceeded. The EL2160C consumes typically 8.5 mA and maximum 11.0 mA. The worst case power in an IC occurs when the output voltage is at half supply, if it can go that far, or its maximum values if it cannot reach half supply. If we set the two PDMAX equations equal to each other, and solve for VS, we can get a family of curves for various loads and output voltages according to: 2060 - 13 The curves do not include heat removal or forcing air, or the simple fact that the package will probably be attached to a circuit board, which can also provide some form of heat removal. Larger temperature and voltage ranges are possible with heat removal and forcing air past the part. RL * (TJMAX b TAMAX) a (VOUT)2 iJA VS e (2 * IS * RL) a VOUT The following curves show supply voltage ( g VS) vs RLOAD for various output voltage swings for the 2 different packages. The curves assume worst case conditions of TA e a 85 C and IS e 11 mA. Current Limit The EL2160C has an internal current limit that protects the circuit in the event of the output being shorted to ground. This limit is set at 100 mA nominally and reduces with junction temperature. At a junction temperature of 150 C, the current limits at about 65 mA. If the output is shorted to ground, the power dissipation could be well over 1W. Heat removal is required in order for the EL2160C to survive an indefinite short. Supply Voltage vs RLOAD for Various VOUT (SO Package) Driving Cables and Capacitive Loads When used as a cable driver, double termination is always recommended for reflection-free performance. For those applications, the back termination series resistor will decouple the EL2160C from the capacitive cable and allow extensive capacitive drive. However, other applications may have high capacitive loads without termination resistors. In these applications, an additional small value (5X -50X) resistor in series with the output will eliminate most peaking. The gain resistor, RG, can be chosen to make up for the gain loss created by this additional series resistor at the output. 2060 - 12 14 EL2160C EL2160C Macromodel * Revision A, November 1993 * AC Characteristics used CINb (pin 2) e 1 pF; RF e 560X a input * Connections: b input * l a Vsupply * l l b Vsupply * l l l output * l l l l * l l l l l .subckt EL2160C/EL 3 2 7 4 6 * * Input Stage * e1 10 0 3 0 1.0 vis 10 9 0V h2 9 12 vxx 1.0 r1 2 11 130 l1 11 12 25nH iinp 3 0 0.5mA iinm 2 0 5mA r12 3 0 2Meg * * Slew Rate Limiting * h1 13 0 vis 600 r2 13 14 1K d1 14 0 dclamp d2 0 14 dclamp * * High Frequency Pole * *e2 30 0 14 0 0.00166666666 l3 30 17 0.43mH c5 17 0 0.27pF r5 17 0 500 * * Transimpedance Stage * g1 0 18 17 0 1.0 ro1 18 0 2Meg cdp 18 0 2.285pF * * Output Stage * q1 4 18 19 qp q2 7 18 20 qn q3 7 19 21 qn q4 4 20 22 qp r7 21 6 4 r8 22 6 4 ios1 7 19 2mA ios2 20 4 2mA * TD is 6.5in * Supply Current * ips 7 4 3mA * * Error Terms * ivos 0 23 2mA vxx 23 0 0V e4 24 0 3 0 1.0 e5 25 0 7 0 1.0 e6 26 0 4 0 1.0 r9 24 23 562 r10 25 23 1K r11 26 23 1K * * Models * .model qn npn (is e 5eb15 bf e 100 tf e 0.1ns) .model qp pnp (is e 5eb15 bf e 100 tf e 0.1ns) .model dclamp d (is e 1eb30 ibv e 0.266 bv e 2.24 n e 4) .ends TD is 2.6in TAB WIDE 130 MHz Current Feedback Amplifier 15 EL2160C EL2160C 130 MHz Current Feedback Amplifier EL2160C Macromodel Contd. 2060 - 14 General Disclaimer Specifications contained in this data sheet are in effect as of the publication date shown. Elantec, Inc. reserves the right to make changes in the circuitry or specifications contained herein at any time without notice. Elantec, Inc. assumes no responsibility for the use of any circuits described herein and makes no representations that they are free from patent infringement. December 1995 Rev B WARNING Life Support Policy Elantec, Inc. products are not authorized for and should not be used within Life Support Systems without the specific written consent of Elantec, Inc. Life Support systems are equipment intended to support or sustain life and whose failure to perform when properly used in accordance with instructions provided can be reasonably expected to result in significant personal injury or death. Users contemplating application of Elantec, Inc. products in Life Support Systems are requested to contact Elantec, Inc. factory headquarters to establish suitable terms & conditions for these applications. Elantec, Inc.'s warranty is limited to replacement of defective components and does not cover injury to persons or property or other consequential damages. Elantec, Inc. 1996 Tarob Court Milpitas, CA 95035 Telephone: (408) 945-1323 (800) 333-6314 Fax: (408) 945-9305 European Office: 44-71-482-4596 16 Printed in U.S.A.