www.cadeka.com KH207 Low Distortion Wideband Op Amp Features n n n n n n n n General Description The KH207 is a wideband, low distortion operational amplifier designed specifically for applications requiring both high speed and wide dynamic range. Utilizing a proprietary current feedback architecture, the KH207 offers performance far superior to that of conventional voltage feedback op amps. -80/-85dBc 2nd/3rd HD at 20MHz -3dB bandwidth of 170MHz 0.1% settling in 22ns Complete overdrive protection 2400V/µs slew rate 3MΩ input resistance Output may be current limited Direct replacement for CLC207 The most attractive feature of the KH207 is its extremely low distortion: -80/-85dBc 2nd/3rd harmonics at 20MHz (2Vpp, RL = 200Ω). The KH207 also provides -3dB bandwidth of 170MHz at a gain of +20, settles to 0.1% in 22ns and slews at a rate of 2400V/µs. The combination of these features positions the KH207 as the right choice for high speed applications requiring exceptional signal purity. Applications n n n n n n Fast, precision A/D conversion Automatic test equipment Input/output amplifiers Photodiode, CCD preamps High-speed modems, radios Line drivers High speed, high resolution A/D and D/A converter systems requiring low distortion operation will find the KH207 an excellent choice. Wide dynamic range systems such as radar and communication receivers will find that the KH207’s low harmonic distortion and low noise make it an attractive high speed solution. The addition of the KH207 to the KH205/206 Series of high speed operational amplifiers broadens the selection of features available from which to choose. The KH205 offers low power operation, the KH206 offers higher drive operation, and the KH207 offers operation with extremely low distortion, all of which are pin compatible and overdrive protected. The KH207 is constructed using thin film resistor/bipolar transistor technology, and is available in the following versions: Bottom View Internal Feedback Case ground GND 7 Rf -VCC 8 9 -VCC 2000Ω Non-Inverting Input 10 V+ 6 Inverting Input V- 5 Not Connected NC 4 Case and bias ground Supply Voltage + 6 - 6 3 2 1 GND NC +VCC -25°C to +85°C -55°C to +125°C KH207AM -55°C to +125°C KH207HXC KH207HXA -55°C to +125°C -55°C to +125°C Collector Supply 11 Vo Output 12 Collector Supply +VCC KH207AI KH207AK Supply Voltage Typical Performance Gain Setting Not Connected Parameter Pin 8 provides access to a 2000Ω feedback resistor which can be connected to the output or left open if an external feedback resistor is desired. 12-pin TO-8 can 12-pin TO-8 can, features burn-in & hermetic testing 12-pin TO-8 can, environmentally screened and electrically tested to MIL-STD-883 SMD#: 5962-9097701HXC SMD#: 5962-9097701HXA -20 -50 Units -3dB bandwidth 220 170 80 220 130 80 rise time 1.7 2.2 4.7 1.7 2.9 4.7 slew rate 2.4 2.4 2.4 2.4 2.4 2.4 settling time (to 0.1%) 22 22 20 21 20 19 MHz ns V/ns ns +7 +20 +50 -1 REV. 1A January 2004 DATA SHEET KH207 KH207 Electrical Characteristics (Av = +20V, VCC = ±15V, RL = 200Ω, Rf = 2kΩ; unless specified) PARAMETERS CONDITIONS Ambient Temperature KH207AI +25°C -25°C +25°C +85°C Ambient Temperature KH207AK/AM/HXC/HXA +25°C -55°C +25°C +125°C FREQUENCY DOMAIN RESPONSE = -3dB bandwidth large-signal bandwidth gain flatness = peaking = peaking = rolloff group delay linear phase deviation Vo <2Vpp Vo <10Vpp Vo <2Vpp 0.1 to 35MHz >35MHz at 70MHz to 70MHz to 50MHz 170 100 >140 >72 >140 >80 0 0 – 3.0 ± .2 0.8 <0.3 <0.8 <0.8 – <3.0 2.2 4.8 22 24 7 2.4 TIME DOMAIN RESPONSE rise and fall time settling time to 0.1% to 0.05% overshoot slew rate 2V step 10V step 10V step, note 2 10V step, note 2 5V step 20Vpp at 50MHz NOISE AND DISTORTION RESPONSE = 2nd harmonic distortion = 2Vpp, 20MHz, RL = 200Ω 2Vpp, 20MHz, RL = 100Ω = 3rd harmonic distortion = 2Vpp, 20MHz, RL = 200Ω 2Vpp, 20MHz, RL = 100Ω equivalent input noise voltage >100kHz inverting current >100kHz non-inverting current >100kHz noise floor >100kHz integrated noise 1kHz to 150MHz integrated noise 5MHz to 150MHz STATIC, DC PERFORMANCE * input offset voltage average temperature coefficient * input bias current average temperature coefficient * input bias current average temperature coefficient * power supply rejection ratio common mode rejection ratio * supply current MISCELLANEOUS PERFORMANCE non-inverting input resistance non-inverting input capacitance output impedance output voltage range internal feedback resistor absolute tolerance temperature coefficient inverting input current self limit non-inverting inverting no load DC 70MHz DC no load TYP MIN & MAX RATINGS UNITS SYM >125 >80 MHz MHz SSBW FPBW <0.3 <0.5 <0.8 – <2.0 <0.5 <0.8 <0.8 – <3.0 dB dB dB ns ° GFPL GFPH GFR GD LPD <2.6 <5.5 <27 <30 <14 >1.8 <2.6 <5.5 <27 <30 <14 >2.0 <3.0 <5.5 <27 <30 <14 >2.0 ns ns ns ns % V/ns TRS TRL TS TSP OS SR -80 -69 -85 -69 <-68 <-64 <-76 <-64 <-76 <-64 <-76 <-64 <-76 <-64 <-76 <-64 dBc dBc dBc dBc HD2 HD2 HD3 HD3 1.6 20 2.2 -158 33 33 <1.8 <23 <2.5 <-157 <38 <38 <1.8 <23 <2.5 <-157 <38 <38 <1.8 <23 <2.5 <-157 <38 <38 3.5 11 3.0 15 2.0 20 69 60 25 <8.0 <25 <25 <100 <22 <150 >55 >50 <27 <8.0 <25 <15 <100 <10 <150 >55 >50 <27 <11.0 <25 <15 <100 <25 <150 >55 >50 <29 mV µV/°C µA nA/°C µA nA/°C dB dB mA VIO DVIO IBN DIBN IBI DIBI PSRR CMRR ICC 3.0 5.0 – ±12 2.0 – – 2.2 >1.0 <7.0 <0.1 >±11 – – – <3.0 >1.0 <7.0 <0.1 >±11 – <0.2 -100 ±40 <3.0 >1.0 <7.0 <0.1 >±11 – – – <3.2 MΩ pF Ω V kΩ % ppm/°C mA RIN CIN RO VO RF RFA RFTC ICL VN nV/√Hz ICN pA/√Hz pA/√Hz NCN dBm(1Hz) SNF µV INV µV INV Min/max ratings are based on product characterization and simulation. Individual parameters are tested as noted. Outgoing quality levels are determined from tested parameters. Absolute Maximum Ratings Recommended Operating Conditions VCC Io common mode input voltage, Vo VCC ±5V to ±15V Io ±100mA common mode input voltage ±(|VCC| -5)V gain range +7 to +50, -1 to -50 note 1: * AI/AK/AM/HXC/HXA 100% tested at +25°C = AK/AM/HXC/HXA 100% tested at +25°C and sample tested at -55°C and +125°C = AI sample tested at +25°C note 2: Settling time specifications require the use of an external feedback resistor (2kΩ). ±20V ±150mA |VCC| > 15V ±(29 - |VCC|)V |VCC| ≤ 15V ±(|VCC| -1)V differential input voltage ±3V thermal resistance (see thermal model) junction temperature +175°C operating temperature AI: -25°C to +85°C AK/AM/HXC/HXA: -55°C to +125°C storage temperature -65°C to +150°C lead temperature (soldering 10s) +300°C 2 REV. 1A January 2004 KH207 DATA SHEET KH207 Typical Performance Characteristics (TA = +25°C,Av = +20,VCC = ±15V, Rf = 20Ω, RL = 200Ω; unless specified) Normalized Magnitude (1dB/div) Inverting Frequency Response Phase (45°/div) Gain Av = +20 Av = +50 Av = +7 Phase Av = +50 Av = +20 0 20 40 60 80 100 120 140 160 180 200 Av = +50 Av = -1 Gain Av = -7 Av = -20 Phase Av = -50 Av = -1 Av = -20 Av = -7 Rf = 3kΩ Rf = 1.5kΩ 0 20 40 60 Rf = 3kΩ 80 100 120 140 160 180 200 0 20 Rf = 2kΩ Rf = 3kΩ 40 60 80 100 120 140 160 180 200 Frequency (MHz) Relative Bandwidth vs. VCC 2 Rf = 1.5kΩ Av = +7 Frequency (MHz) Large Signal Gain and Phase Gain and Phase for Various Loads 2 2 1.0 Vo = 10Vpp RL = 50Ω Magnitude (1dB/div) Phase RL = 100Ω Gain 0.8 0.7 0.6 0.5 0.4 RL = 200Ω RL = 1kΩ Phase Phase (45°/div) Phase (45°/div) Gain Relative Bandwidth 0.9 Magnitude (1dB/div) Rf = 2kΩ Av = +20 Av = -50 Frequency (MHz) Rf = 1.5kΩ Rf = 2kΩ Relative Gain (5dB/div) Av = +7 Frequency Response vs. External Rf Phase (45°/div) Normalized Magnitude (1dB/div) Non-Inverting Frequency Response RL = 1kΩ RL = 200Ω RL = 100Ω RL = 50Ω 0.3 0.2 0 15 30 45 60 75 90 105 120 135 150 4 6 8 Small Signal Pulse Response 12 14 0 16 20 40 Large Signal Pulse Response 2 Av = -20 80 100 120 140 160 180 200 Settling Time 2 2 0.20 10V step Rf = 2kΩ (external) 0.15 Av = +20 Output Voltage (2V/div) Av = +20 60 Frequency (MHz) Settling Error (%) Output Voltage (0.4V/div) 10 ±VCC (V) Frequency (MHz) 0.10 0.05 0 -0.05 -0.10 -0.15 Av = -20 -0.20 Time (5ns/div) 2nd and 3rd Harmonic Distortion 2 Distortion (dBc) -50 2nd -60 -65 -70 -75 -20 -20 -30 -30 16Vpp -40 8Vpp -50 -60 4Vpp -70 2Vpp -80 -80 3rd -85 -90 10 100 1 10 2Vpp -70 100 1 10 45 Interdept Point (dBm) PSRR CMRR 40 20 Equivalent Input Noise 2-Tone, 3rd Order Intermod. Intercept K 40 K 100 100 Pout 50Ω 35 30 25 20 Inverting Current 20pA√Hz 10 10 Non-Inverting Current 2.2pA√Hz Noise Current (pA√Hz) 80 100 Frequency (MHz) 50Ω PSRR and CMRR (dB) -60 Frequency (MHz) K 4Vpp 8Vpp -50 1Vpp Noise Voltage (nV√Hz) CMRR and PSRR -40 -90 Frequency (MHz) 100 16Vpp -80 1Vpp -90 1 60 Distortion (dBc) -45 -55 3rd Harmonic Distortion, RL = 100Ω2 2nd Harmonic Distortion, RL = 100Ω 2 -40 Distortion (dBc) Time (5ns/div) Time (5ns/div) Voltage 1.6nV/√Hz 100 1k 10k 100k 1M 10M 100M 2 REV. 1A January 2004 0 10 20 30 40 50 60 70 80 90 100 102 103 104 105 106 107 108 Frequency (Hz) Frequency (MHz) Frequency (Hz) 1 1 15 0 K K 3 DATA SHEET KH207 Current Feedback Amplifiers Some of the key features of current feedback technology are: n Independence of AC bandwidth and voltage gain n Adjustable frequency response with feedback resistor n High slew rate n Fast settling Short Circuit Protection Damage caused by short circuits at the output may be prevented by limiting the output current to safe levels. The most simple current limit circuit calls for placing resistors between the output stage collector supplies and the output stage collectors (pins 12 and 10). The value of this resistor is determined by: Current feedback operation can be described using a simple equation. The voltage gain for a non-inverting or inverting current feedback amplifier is approximated by Equation 1. V RC = C − RI II Vo Av = Vin 1 + R f Z( jω ) Equation 1 where: n n n n where II is the desired limit current and RI is the minimum expected load resistance (0Ω for a short to ground). Bypass capacitors of 0.01µF on should be used on the collectors as in Figures 2 and 3. Av is the closed loop DC voltage gain Rf is the feedback resistor Z(jω) is the CLC205’s open loop transimpedance gain n n n n 6 5 + Vo Rg common mode protection Figure 1: Diode Clamp Circuits for Common Mode and Differential Mode Protection K 11 - Vo 200Ω 3,7 9 Rf Rg Rf = 2000Ω (internal) 33Ω 3.9 A v = 1+ .1 .01 33Ω +15V 3.9 differential protection KH207 8 10 -15V Capactance in µF .1 50Ω 6 -Vcc 12 KH207 Figure 2: Recommended Non-Inverting Gain Circuit Overdrive Protection Unlike most other high-speed op amps, the KH207 is not damaged by saturation caused by overdriving input signals (where Vin x gain > max. Vo). The KH207 self limits the current at the inverting input when the output is saturated (see the inverting input current self limit specification); this ensures that the amplifier will not be damaged due to excessive internal currents during overdrive. For protection against input signals which would exceed either the maximum differential or common mode input voltage, the diode clamp circuits below may be used. 4 1 + Rg Decreases loop gain Decreases bandwidth Reduces gain peaking Lowers pulse response overshoot Affects frequency response phase linearity +Vcc .01 Ri 50Ω Vin Capactance in µF .1 Vin Z( jω ) is the loop gain Rf The denominator of Equation 1 is approximately equal to 1 at low frequencies. Near the -3dB corner frequency, the interaction between Rf and Z(jω) dominates the circuit performance. The value of the feedback resistor has a large affect on the circuits performance. Increasing Rf has the following affects: n 33Ω +15V 3.9 Rg 5 Vin .01 1 + 12 8 11 KH207 Vo 10 - 200Ω 3,7 9 Ri Av = 33Ω -15V 3.9 .1 .01 -R f Rg Rf = 2000Ω (internal) For Zin = 50Ω, select Rg||Ri = 50Ω Figure 3: Recommended Inverting Gain Circuit A more sophisticated current limit circuit which provides a limit current independent of RI is shown in Figure 4 on page 5. With the component values indicated, current limiting occurs at 50mA. For other values of current limit (II), select RC to equal Vbe/lI. Where Vbe is the base to emitter voltage drop of Q3 (or Q4) at a current of [2VCC – 1.4] / Rx, where Rx ≤ [(2VCC – 1.4) / II] Bmin. Also, Bmin is the minimum beta of Q1 (or Q2) at a current of II. Since the limit current depends on Vbe, which is temperature dependent, the limit current is likewise temperature dependent. REV. 1A January 2004 KH207 DATA SHEET +Vcc Rc 12Ω Q3 (2N3906) Noise Analysis Approximate noise figure can be determined for the KH207 using the Equivalent Input Noise plot on page 3 and the equations shown below. Q1 (MJE170) kT = 4.00 x 10-21 Joules at 290°K Vn is spot noise voltage (V/√Hz) in is non-inverting spot noise current (A/√Hz) ii is inverting spot noise current (A/√Hz) 0.01ΩF to pin 12 Rx 14.3kΩ to pin 10 0.01ΩF Rs Q2 (MJE180) + Rn Q4 (2N3904) Rc 12Ω Ro KH207 Rf Rg -Vcc Figure 4: Active Current Limit Circuit (50mA) Controlling Bandwidth and Passband Response K In most applications, a feedback resistor value of 2kΩ will provide optimum performance; nonetheless, some applications may require a resistor of some other value. The response versus Rf plot on the previous page shows how decreasing Rf will increase bandwidth (and frequency response peaking, which may lead to instability). Conversely, large values of feedback resistance tend to roll off the response. The best settling time performance requires the use of an external feedback resistor (use of the internal resistor results in a 0.1% to 0.2% settling tail). The settling performance may be improved slightly by adding a capacitance of 0.4pF in parallel with the feedback resistor (settling time specifications reflect performance with an external feedback resistor but with no external capacitance). Thermal Model R 2f i i2 Rs R s 2 V n2 F = 10 log 1 + + ⋅ in + + R n 4 kT R p2 R p2 A 2v where R p = Rs Rn Rs +Rn ; Av = Rf Rg +1 Figure 5: Noise Figure Diagram and Equations (Noise Figure is for the Network Inside this Box.) Driving Cables and Capacitive Loads When driving cables, double termination is used to prevent reflections. For capacitive load applications, a small series resistor at the output of the KH207 will improve stability and settling performance. Transmission Line Matching One method for matching the characteristic impedance (Zo) of a transmission line or cable is to place the appropriate resistor at the input or output of the amplifier. Figure 6 shows typical inverting and non-inverting circuit configurations for matching transmission lines. Tcase 100°C/W Tj(pnp) Ppnp 100°C/W Tj(npn) Pnpn 17.5°C/W θca R1 Z0 R3 Tj(circuit) Pcircuit V1 +- + Tambient Pcircuit = [(+VCC) – (-VCC)]2 / 1.77kΩ Pxxx = [(±VCC) – Vout – (Icol) (Rcol + 6)] (Icol) (% duty cycle) (For positive Vo and VCC, this is the power in the npn output stage.) (For negative Vo and VCC, this is the power in the pnp output stage.) θca = 65°C/W in still air without a heatsink. 35°C/W in still air without a Thermalloy 2268. 15°C/W in 300ft/min air with a Thermalloy 2268 (Thermalloy 2240 works equally well.) Icol = Vout/Rload or 3mA, whichever is greater. (Include feedback R in Rload.) Rcol is a resistor (33Ω recommended) between the xxx collector and ±VCC. Tj (pnp) = Ppnp (100 + θca) + (Pcir + Pnpn)θca + Ta, similar for Tj (npn). R2 R4 V2 +- Z0 Rg C6 + Z0 KH207 - R6 Vo R7 Rf R5 Figure 6: Transmission Line Matching Non-inverting gain applications: n n n Connect Rg directly to ground. Make R1, R2, R6, and R7 equal to Zo. Use R3 to isolate the amplifier from reactive loading caused by the transmission line, or by parasitics. Tj (cir) = Pcir (17.5 + θca) + (Ppnp + Pnpn)θca + Ta. REV. 1A January 2004 5 DATA SHEET Inverting gain applications: n n n Connect R3 directly to ground. Make the resistors R4, R6, and R7 equal to Zo. Make R5 II Rg = Zo. The input and output matching resistors attenuate the signal by a factor of 2, therefore additional gain is needed. Use C6 to match the output transmission line over a greater frequency range. C6 compensates for the increase of the amplifier’s output impedance with frequency. Dynamic Range (Intermods) For RF applications, the KH207 specifies a third order intercept of 26dBm at 60MHz and Po = 10dBm. A 2-Tone, 3rd Order IMD Intercept plot is found in the Typical Performance Characteristics section. The output power level is taken at the load. Third-order harmonic distortion is calculated with the formula: HD 3rd = 2 • (IP3o – Po) n n n IP3o = third-order output intercept, dBm at the load. Po = output power level, dBm at the load. HD 3 rd = third-order distortion from the fundamental, -dBc. dBm is the power in mW, at the load, expressed in dB. Realized third-order output distortion is highly dependent upon the external circuit. Some of the common external circuit choices that improve 3rd order distortion are: n n n n 6 Printed Circuit Layout As with any high frequency device, a good PCB layout will enhance the performance of the KH207. Good ground plane construction and power supply bypassing close to the package are critical to achieving full performance. In the non-inverting configuration, the amplifier is sensitive to stray capacitance to ground at the inverting input. Hence, the inverting node connections should be small with minimal stray capacitance to the ground plane or other nodes. Shunt capacitance across the feedback resistor should not be used to compensate for this effect. General layout and supply bypassing play major roles in high frequency performance. Follow the steps below as a basis for high frequency layout: n n n where: n KH207 short and equal return paths from the load to the supplies. de-coupling capacitors of the correct value. higher load resistance. a lower ratio of the output swing to the power supply voltage. n n n Include 6.8µF tantalum and 0.1µF ceramic capacitors on both supplies. Place the 6.8µF capacitors within 0.75 inches of the power pins. Place the 0.1µF capacitors less than 0.1 inches from the power pins. Remove the ground plane under and around the part, especially near the input and output pins to reduce parasitic capacitance. Minimize all trace lengths to reduce series inductances. Use flush-mount printed circuit board pins for prototyping, never use high profile DIP sockets. An evaluation PC board (part number 730009) for the KH207 is available to aid in device testing. REV. 1A January 2004 DATA SHEET KH207 KH207 Package Dimensions L A e1 e2 7 φD e D1 8 9 6 10 5 11 4 12 k φb 3 2 1 α F k1 TO-8 SYMBOL INCHES Minimun MILIMETERS Maximum Minimum Maximum A 0.142 0.181 3.61 4.60 φb 0.016 0.019 0.41 0.48 φD 0.595 0.605 15.11 15.37 φD1 0.543 0.555 13.79 14.10 e 0.400 BSC 10.16 BSC e1 0.200 BSC 5.08 BSC e2 0.100 BSC 2.54 BSC F 0.016 0.030 0.41 0.76 k 0.026 0.036 0.66 0.91 k1 0.026 0.036 0.66 0.91 L 0.310 0.340 7.87 8.64 α 45° BSC NOTES: Seal: cap weld Lead finish: gold per MIL-M-38510 Package composition: Package: metal Lid: Type A per MIL-M-38510 45° BSC Life Support Policy Cadeka’s products are not authorized for use as critical components in life support devices or systems without the express written approval of the president of Cadeka Microcircuits, Inc. As used herein: 1. Life support devices or systems are devices or systems which, a) are intended for surgical implant into the body, or b) support or sustain life, and whose failure to perform, when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user. 2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness. Cadeka does not assume any responsibility for use of any circuitry described, and Cadeka reserves the right at any time without notice to change said circuitry and specifications. www.cadeka.com © 2004 Cadeka Microcircuits, LLC