www.cadeka.com KH103 Fast Settling, High Current Wideband Op Amp Features n n n n n n 80MHz full-power bandwidth (20Vpp, 100Ω) 200mA output current 0.4% settling in 10ns 6000V/µs slew rate 4ns rise and fall times (20V) Direct replacement for CLC103 Applications n n n n n Coaxial line driving DAC current to voltage amplifier Flash A to D driving Baseband and video communications Radar and IF processors Small Signal Pulse Response General Description The KH103 is a high-power, wideband op amp designed for the most demanding high-speed applications. The wide bandwidth, fast settling, linear phase, and very low harmonic distortion provide the designer with the signal fidelity needed in applications such as driving flash A to Ds. The 80MHz full-power bandwidth and 200mA output current of the KH103 eliminate the need for power buffers in most applications; the KH103 is an excellent choice for driving large highspeed signals into coaxial lines. In the design of the KH103 special care was taken in order to guarantee that the output settle quickly to within 0.4% of the final value for use with ultra fast flash A to D converters. This is one of the most demanding of all op amp requirements since settling time is affected by the op amps bandwidth, passband gain flatness, and harmonic distortion. This high degree of performance ensures excellent performance in many other demanding applications as well. The dynamic performance of the KH103 is based on a current feedback topology that provides performance far beyond that available from conventional op amp designs. Unlike conventional op amps where optimum gain-bandwidth product occurs at a high gain, minimum settling time at a gain of -1, and maximum slew rate at a gain of +1, the KH103 provides consistent predictable performance across its entire gain range. For example, the table below shows how the -3dB bandwidth remain nearly constant over a wide range of gains. And since the amplifier is inherently stable, no external compensation is required. The result is shorter design time and the ability to accommodate design changes (in gain, for example) without loss of performance or redesign of compensation circuits. The KH103 is constructed using thin film resistor/ bipolar transistor technology, and is available in the following versions: KH103AI KH103AK Typical Performance KH103AM -25°C to +85°C 24-pin Ceramic DIP -55°C to +125°C 24-pin Ceramic DIP, features burn-in and hermetic testing -55°C to +125°C 24-pin Ceramic DIP, environmentally screened and electronically tested to MIL-STD-883 REV. 1A January 2004 DATA SHEET KH103 KH103 Electrical Characteristics (Av = +20V, VCC = ±15V, RL = 100Ω; unless noted) Absolute Maximum Ratings VCC (reversed supplies will destroy part) junction temperature (see thermal model) thermal resistance storage temperature lead temperature (soldering 10s) output current operating temperature: AI AK, AM ±20V +175°C see thermal model -65°C to +150°C +300°C ±200mA -25°C to +85°C -55C to +125°C Notes 1) * AI, AK, AM 100% tested at +25°C = AK, AM 100% tested at at +25°C and sample tested at -55°C and +125°C = AI sample tested at +25°C 2) This rating protects against damage to the input stage caused by saturation of either the input or output stages. Under transient conditions not exceeding 1µs (duty cycle not exceeding 10% maximum input voltage may be as large as twice the maximum Vcm should never exceed ±5V. (Vcm is the voltage at the non-inverting input, pin 7). 3) This rating protects against exceeding transistor collector-emitter breakdown ratings. Recommended VCC is ±15V. 2 REV. 1A January 2004 KH103 KH103 Performance Characteristics REV. 1A January 2004 DATA SHEET (Av = +20°C, VCC = ±15V, RL = 100Ω; unless noted) 3 DATA SHEET KH103 KH103 Operation The KH103 is based on a unique design which uses current feedback instead of the usual voltage feedback. This design provides dynamic performance far beyond that previously available, yet it is used basically the same as the familiar voltage-feedback op amp (see the gain equations above). Layout Considerations To obtain optimum performance from any circuit operating at high frequencies, good PC layout is essential. Fortunately, the stable, well-behaved response of the KH103 makes operation at high frequencies less sensitive to layout than is the case with other wideband op amps, even though the KH103 has a much wider bandwidth. Figure 2: Recommended Inverting Gain Circuit In general, a good layout is one which minimizes the unwanted coupling of a signal between nodes in a circuit. A continuous ground plane from the signal input to output on the circuit side of the board is helpful. Traces should be kept short to minimize inductance. If long traces are needed, use microstrip transmission lines which are terminated in their characteristic impedance. At some high-impedance nodes, or in sensitive areas such as near pin 5 of the KH103, stray capacitance should be kept small by keeping nodes small and removing ground plans directly around the node. Since the layout of the PC board forms such an important part of the circuit, much time can be saved if prototype amplifier boards are tested early in the design stage. The ±VCC connections to the KH103 are internally bypassed to ground with 0.1µF capacitors to provide good high-frequency decoupling. It is recommended that 1µF or larger tantalum capacitors be provided for lowfrequency decoupling. The 0.01µF capacitors shown at pins 18 and 20 in figures 1 and 2 should be kept within 0.1” of those pins. A wide strip of ground plane should be provided for a signal return path between the load-resistors ground and these capacitors. A composite amplifier can also be referred to as a feedforward amplifier. Most feed-forward techniques such as those used In the vast majority of wideband op amps involve the use of a wideband AC-coupled channel in parallel with a low-bandwidth, high-gain DC-coupled amplifier. For the composite amplifier suggested for use with the KH103, the KH103 replaces the wideband ACcoupled amplifier and a low-cost monolithic op amp is used to supply high open-loop gain at low frequencies. Since the KH103 is strictly DC coupled throughout, crossover distortion of less than 0.01dB and 1° results. Figure 1: Recommended Non-Inverting Gain Circuit 4 Settling Time, Offset, and Drift After an output transition has occurred. the output settles very rapidly to the final value and no change occurs for several microseconds. Thereafter, thermal gradients inside the KH103 will cause the output to begin to drift. When this cannot be tolerated, or when the initial offset voltage and drift is unacceptable, use of a composite amplifier is advised. For composite operation in the non-inverting mode, the circuit in Figure 1 should be modified by the addition of the circuit shown in Figure 3. For Inverting operation, modify the circuit in Figure 2 by the addition of the circuit in Figure 4. Keep all resistors which connect to the KH103 within 0.2” of the KH103 pins. The other side of these resistors should likewise be as close to U1 as possible. For good overall results, U1 should be similar to the LF356; this gives 5mV/°C input offset drift and the crossover frequency occurs at about 2MHz. Since U1 has a feedback network composed of Ra + Rb and a 15kΩ resistor, which is in parallel with Rg and the internal 1.5kΩ feedback resistor of the KH103, Rb must be adjusted to match the feedback ratios of the two networks. This in done by driving the composite amplifier REV. 1A January 2004 KH103 with a 70kHz square wave large enough to produce a transition from +5V to -5V at the KH103 output and adjusting Rb until the output of U1 is at a minimum. Ra should be about 9.5Rg for bad results; thus, Rb should be adjusted around the value of 0.5Rg. DATA SHEET Distortion and Noise The graphs of intercept point versus frequency on the page 3 make it easy to predict the distortion at any frequency, given the output voltage of the KH103. First convert the output voltage Vo to Vrms = (Vpp/2√2) and then to P = (10log10 (20Vrms2)) to get the output power in dBm. At the frequency of interest, its 2nd harmonic will be S2 = (I2 - P) dB below the level of P. Its third harmonic will be S3 = 2(I3 - P) dB below the level of P, as will the two-tone third order intermodulation products. These approximations are useful for P < -1dB compression levels. Approximate noise figure can determined for the KH103 using the Equivalent Input Noise graph on page 3. The following equation can be used to determine noise figure (F) in dB. Figure 3: Non-Inverting Gain Composite Amplifier to be Used with Figure 1 Circuit Figure 4: Inverting Gain Composite Amplifier to be Used with Figure 2 Circuit where vn is the rms noise voltage and in is the rms noise current. Beyond the breakpoint of the curves (i.e. where they are flat) broadband noise figure equals spot noise, so ∆f should equal one (1) and vn and in should be read directly off the graph. Below the breakpoint, the noise must be integrated and ∆f set to the appropriate bandwidth. Bias Control In normal operation, the bias control pin (pin 16) is left unconnected. However, if control over the bias of the amplifier is desired, the bias control pin may be driven with a TTL signal; a TTL high level will turn the amplifier off. REV. 1A January 2004 5 DATA SHEET KH103 KH103 Package Dimensions 2 C b1 Pin #1 Index Q A L b E1 E e D1 A1 D Symbol Inches Milimeters Minimun Maximum Minimum Maximum A-Metal Lid 0.180 0.240 4.57 6.10 A-Ceramic Lid 0.195 0.255 4.95 6.48 A1-Metal Lid 0.145 0.175 3.68 4.45 A1-Ceramic Lid 0.160 0.190 4.06 4.83 b 0.014 0.026 0.36 0.66 b1 0.050 BSC 1.27 BSC c 0.008 0.018 0.20 0.46 D 1.275 1.310 33.39 33.27 D1 1.095 1.105 27.81 28.07 E 0.785 0.815 19.94 20.70 E1 0.790 0.810 20.07 20.57 e 0.100 BSC 2.54 BSC L 0.165 BSC 4.19 BSC Q 0.015 0.075 NOTES: NOTES: Seal: seam weld (AM, AK), epoxy (AI) Lead finish: gold finish Package composition: Package: ceramic Lid: kovar/nickel (AM, AK), ceramic (AI) Leadframe: alloy 42 Die attach: epoxy 0.38 1.91 © 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