LT1210 1.1A, 35MHz Current Feedback Amplifier U DESCRIPTIO FEATURES ■ ■ ■ ■ ■ ■ ■ ■ ■ 1.1A Minimum Output Drive Current 35MHz Bandwidth, AV = 2, RL = 10Ω 900V/µs Slew Rate, AV = 2, RL = 10Ω High Input Impedance: 10MΩ Wide Supply Range: ±5V to ±15V (TO-220 and DD Packages) Enhanced θJA SO-16 Package for ±5V Operation Shutdown Mode: IS < 200µA Adjustable Supply Current Stable with CL = 10,000pF U APPLICATIONS ■ ■ ■ ■ ■ Cable Drivers Buffers Test Equipment Amplifiers Video Amplifiers ADSL Drivers The LT ®1210 is a current feedback amplifier with high output current and excellent large-signal characteristics. The combination of high slew rate, 1.1A output drive and ±15V operation enables the device to deliver significant power at frequencies in the 1MHz to 2MHz range. Shortcircuit protection and thermal shutdown ensure the device’s ruggedness. The LT1210 is stable with large capacitive loads, and can easily supply the large currents required by the capacitive loading. A shutdown feature switches the device into a high impedance and low supply current mode, reducing dissipation when the device is not in use. For lower bandwidth applications, the supply current can be reduced with a single external resistor. The LT1210 is available in the TO-220 and DD packages for operation with supplies up to ±15V. For ±5V applications the device is also available in a low thermal resistance SO-16 package. , LTC and LT are registered trademarks of Linear Technology Corporation. U TYPICAL APPLICATIO S Twisted Pair Driver Total Harmonic Distortion vs Frequency 15V –50 4.7µF* 100nF RT 11Ω 2.5W + VIN LT1210 SD – + T1** 1 4.7µF* –15V 3 RL 100Ω 2.5W 100nF 845Ω * TANTALUM ** MIDCOM 671-7783 OR EQUIVALENT TOTAL HARMONIC DISTORTION (dB) + VS = ±15V VOUT = 20VP-P AV = 4 –60 –70 RL = 12.5Ω –80 RL = 10Ω RL = 50Ω –90 –100 1k 274Ω 10k 100k FREQUENCY (Hz) 1M 1210 TA01 1210 TA02 1 LT1210 W W W AXI U U ABSOLUTE RATI GS Supply Voltage ..................................................... ±18V Input Current .................................................... ±15mA Output Short-Circuit Duration (Note 1) ....... Continuous Specified Temperature Range (Note 2) ...... 0°C to 70°C Operating Temperature Range ............... –40°C to 85°C Junction Temperature ......................................... 150°C Storage Temperature Range ................. – 65°C to 150°C Lead Temperature (Soldering, 10 sec)................. 300°C W U U PACKAGE/ORDER INFORMATION TOP VIEW FRONT VIEW TAB IS V + 7 6 5 4 3 2 1 OUT V– COMP V+ SHUTDOWN +IN –IN R PACKAGE 7-LEAD PLASTIC DD θJA ≈ 25°C/W V+ 1 16 V + V+ 2 15 NC OUT 3 14 V – V+ 4 13 COMP NC 5 12 SHUTDOWN –IN 6 11 +IN NC 7 10 NC V+ 8 9 FRONT VIEW 7 6 5 4 3 2 1 TAB IS V + OUT V– COMP V+ SHUTDOWN +IN –IN T7 PACKAGE 7-LEAD TO-220 V+ S PACKAGE 16-LEAD PLASTIC SO θJC = 5°C/W θJA ≈ 40°C/W (Note 3) ORDER PART NUMBER ORDER PART NUMBER ORDER PART NUMBER LT1210CR LT1210CS LT1210CT7 Consult factory for Industrial and Military grade parts. ELECTRICAL CHARACTERISTICS VCM = 0V, ±5V ≤ VS ≤ ±15V, pulse tested, VSD = 0V, unless otherwise noted. SYMBOL PARAMETER CONDITIONS VOS Input Offset Voltage TA = 25°C MIN TYP MAX UNITS ±3 ±15 ±20 mV mV ● Input Offset Voltage Drift IIN+ Noninverting Input Current ±2 ±5 ±20 µA µA ±10 ±60 ±100 µA µA ● IIN– Inverting Input Current µV/°C 10 ● TA = 25°C TA = 25°C ● en Input Noise Voltage Density f = 10kHz, RF = 1k, RG = 10Ω, RS = 0Ω 3.0 nV/√Hz + in Input Noise Current Density f = 10kHz, RF = 1k, RG = 10Ω, RS = 10k 2.0 pA/√Hz – in Input Noise Current Density f = 10kHz, RF = 1k, RG = 10Ω, RS = 10k 40 pA/√Hz RIN Input Resistance VIN = ±12V, VS = ±15V VIN = ±2V, VS = ±5V 10 5 MΩ MΩ CIN Input Capacitance VS = ±15V 2 pF Input Voltage Range VS = ±15V VS = ±5V ±13.5 ±3.5 V V 2 ● ● ● ● 1.50 0.25 ±12 ±2 LT1210 ELECTRICAL CHARACTERISTICS VCM = 0V, ±5V ≤ VS ≤ ±15V, pulse tested, VSD = 0V, unless otherwise noted. SYMBOL PARAMETER CONDITIONS CMRR Common Mode Rejection Ratio VS = ±15V, VCM = ±12V VS = ±5V, VCM = ±2V ● ● Inverting Input Current Common Mode Rejection VS = ±15V, VCM = ±12V VS = ±5V, VCM = ±2V ● ● Power Supply Rejection Ratio VS = ±5V to ±15V ● Noninverting Input Current Power Supply Rejection VS = ±5V to ±15V ● Inverting Input Current Power Supply Rejection VS = ±5V to ±15V ● Large-Signal Voltage Gain TA = 25°C, VS = ±15V, VOUT = ±10V, RL = 10Ω (Note 3) PSRR AV ROL VOUT Transresistance, ∆VOUT/∆IIN– Maximum Output Voltage Swing MIN TYP 55 50 62 60 µA/V µA/V 30 500 nA/V 0.7 5 µA/V 77 dB 55 71 dB ● 55 68 dB VS = ±5V, VOUT = ±2V, RL = 10Ω ● 55 68 dB 100 260 kΩ 75 200 kΩ kΩ TA = 25°C, VS = ±15V, VOUT = ±10V, RL = 10Ω (Note 3) VS = ±15V, VOUT = ±8.5V, RL = 10Ω (Note 3) ● VS = ±5V, VOUT = ±2V, RL = 10Ω ● 75 200 ±11.5 ● ±10.0 ±8.5 V V ±2.5 ±2.0 ±3.0 ● V V ● 1.1 2.0 TA = 25°C, VS = ±15V, RL = 10Ω (Note 3) IOUT Maximum Output Current (Note 3) VS = ±15V, RL = 1Ω IS Supply Current (Note 3) TA = 25°C, VS = ±15V, VSD = 0V Supply Current, RSD = 51k (Notes 3, 4) TA = 25°C, VS = ±15V Positive Supply Current, Shutdown VS = ±15V, VSD = 15V ● ● Output Leakage Current, Shutdown VS = ±15V, VSD = 15V Slew Rate (Note 5) Slew Rate (Note 3) TA = 25°C, AV = 2, RL = 400Ω TA = 25°C, AV = 2, RL = 10Ω Differential Gain (Notes 3, 6) A 35 50 65 mA mA 15 30 mA 200 µA ● BW dB dB VS = ±15V, VOUT = ±8.5V, RL = 10Ω (Note 3) TA = 25°C, VS = ±5V, RL = 10Ω SR UNITS 10 10 0.1 0.1 60 MAX 10 µA 900 900 V/µs V/µs VS = ±15V, RF = 750Ω, RG = 750Ω, RL = 15Ω 0.3 % Differential Phase (Notes 3, 6) VS = ±15V, RF = 750Ω, RG = 750Ω, RL = 15Ω 0.1 DEG Small-Signal Bandwidth AV = 2, VS = ±15V, Peaking ≤ 1dB, RF = RG = 680Ω, RL = 100Ω 55 MHz AV = 2, VS = ±15V, Peaking ≤ 1dB, RF = RG = 576Ω, RL = 10Ω 35 MHz The ● denotes specifications which apply for 0°C ≤ TA ≤ 70°C. Note 1: Applies to short circuits to ground only. A short circuit between the output and either supply may permanently damage the part when operated on supplies greater than ±10V. Note 2: Commercial grade parts are designed to operate over the temperature range of – 40°C ≤ TA ≤ 85°C, but are neither tested nor guaranteed beyond 0°C ≤ TA ≤ 70°C. Industrial grade parts tested over – 40°C ≤ TA ≤ 85°C are available on special request. Consult factory. Note 3: SO package is recommended for ±5V supplies only, as the power dissipation of the SO package limits performance on higher supplies. For 400 supply voltages greater than ±5V, use the TO-220 or DD package. See “Thermal Considerations” in the Applications Information section for details on calculating junction temperature. If the maximum dissipation of the package is exceeded, the device will go into thermal shutdown. Note 4: RSD is connected between the Shutdown pin and ground. Note 5: Slew rate is measured at ±5V on a ±10V output signal while operating on ±15V supplies with RF = 1.5k, RG = 1.5k and RL = 400Ω. Note 6: NTSC composite video with an output level of 2V. 3 LT1210 W SMALL-SIGNAL BANDWIDTH U U RSD = 0Ω, IS = 30mA, VS = ±5V, Peaking ≤ 1dB RSD = 0Ω, IS = 35mA, VS = ±15V, Peaking ≤ 1dB AV RL RF RG – 3dB BW (MHz) –1 150 30 10 150 30 10 150 30 10 150 30 10 549 590 619 604 649 619 562 590 576 392 383 215 549 590 619 – – – 562 590 576 43.2 42.2 23.7 52.5 39.7 26.5 53.5 39.7 27.4 51.8 38.8 27.4 48.4 40.3 36.0 1 2 10 RSD = 7.5k, IS = 15mA, VS = ±5V, Peaking ≤ 1dB RL RF RG – 3dB BW (MHz) –1 150 30 10 150 30 10 150 30 10 150 30 10 562 619 604 634 681 649 576 604 576 324 324 210 562 619 604 – – – 576 604 576 35.7 35.7 23.2 39.7 28.9 20.5 41.9 29.7 20.7 40.2 29.6 21.6 39.5 32.3 27.7 2 10 RSD = 15k, IS = 7.5mA, VS = ±5V, Peaking ≤ 1dB RL RF RG – 3dB BW (MHz) –1 150 30 10 150 30 10 150 30 10 150 30 10 536 549 464 619 634 511 536 549 412 150 118 100 536 549 464 – – – 536 549 412 16.5 13.0 11.0 28.2 20.0 15.0 28.6 19.8 14.9 28.3 19.9 15.7 31.5 27.1 19.4 2 10 4 RF RG – 3dB BW (MHz) –1 150 30 10 150 30 10 150 30 10 150 30 10 604 649 665 750 866 845 665 715 576 453 432 221 604 649 665 – – – 665 715 576 49.9 47.5 24.3 66.2 48.4 46.5 56.8 35.4 24.7 52.5 38.9 35.0 61.5 43.1 45.5 1 2 10 AV RL RF RG – 3dB BW (MHz) –1 150 30 10 150 30 10 150 30 10 150 30 10 619 698 698 732 806 768 634 698 681 348 357 205 619 698 698 – – – 634 698 681 38.3 39.2 22.6 47.8 32.3 22.2 51.4 33.9 22.5 48.4 33.0 22.5 46.8 36.7 31.3 1 2 10 RSD = 82.5k, IS = 9mA, VS = ±15V, Peaking ≤ 1dB AV 1 RL RSD = 47.5k, IS = 18mA, VS = ±15V, Peaking ≤ 1dB AV 1 AV AV RL RF RG – 3dB BW (MHz) –1 150 30 10 150 30 10 150 30 10 150 30 10 590 649 576 715 768 649 590 665 549 182 182 100 590 649 576 – – – 590 665 549 20.0 20.0 11.0 34.8 22.5 16.3 35.5 22.5 16.1 35.3 22.5 16.8 37.2 28.9 22.5 1 2 10 LT1210 W U TYPICAL PERFOR A CE CHARACTERISTICS 50 100 –3dB BANDWIDTH (MHz) 70 RF = 560Ω 60 50 RF = 750Ω 40 RF = 680Ω 30 RF = 1k 40 RF = 560Ω 30 RF = 750Ω RF = 1k 20 RF = 2k 10 20 FEEDBACK RESISTANCE AV = 2 RL = ∞ VS = ±15V CCOMP = 0.01µF 100 0 0 4 14 12 10 8 SUPPLY VOLTAGE (±V) 6 16 4 18 14 12 10 8 SUPPLY VOLTAGE (±V) 6 16 18 1 Bandwidth vs Supply Voltage 1210 G03 Bandwidth and Feedback Resistance vs Capacitive Load for Peaking ≤ 5dB Bandwidth vs Supply Voltage 50 PEAKING ≤ 1dB PEAKING ≤ 5dB 90 50 – 3dB BANDWIDTH (MHz) RF =390Ω 60 RF = 330Ω RF = 470Ω 40 RF = 680Ω 30 30 20 10 RF = 560Ω RF = 1k 10 20 BANDWIDTH 40 RF = 680Ω 100 AV = 10 RL = 10Ω 1k AV = +2 RL = ∞ VS = ±15V CCOMP = 0.01µF RF = 1.5k RF = 1.5k 100 0 0 0 4 14 12 10 8 SUPPLY VOLTAGE (±V) 6 16 4 18 14 12 10 8 SUPPLY VOLTAGE (±V) 6 16 1 18 1210 G06 Differential Gain vs Supply Voltage Differential Phase vs Supply Voltage Spot Noise Voltage and Current vs Frequency 100 0.5 0.6 RF = RG = 750Ω AV = 2 RL = 10Ω DIFFERENTIAL GAIN (%) 0.4 0.4 RF = RG = 750Ω AV = 2 0.3 RL = 15Ω 0.2 RL = 50Ω RL = 10Ω 0.3 RL = 15Ω 0.2 0.1 0.1 RL = 50Ω RL = 30Ω RL = 30Ω 0 5 7 11 13 9 SUPPLY VOLTAGE (±V) 15 1210 G07 1 10000 10 100 1000 CAPACITIVE LOAD (pF) 1210 G05 1210 G04 0.5 10 FEEDBACK RESISTANCE –3dB BANDWIDTH (MHz) 80 70 10k PEAKING ≤ 1dB AV = 10 RL = 100Ω FEEDBACK RESISTANCE (Ω) 100 1 10000 10 100 1000 CAPACITIVE LOAD (pF) 1210 G02 1210 G01 –3dB BANDWIDTH (MHz) 10 1k RF = 1.5k 10 DIFFERENTIAL PHASE (DEG) BANDWIDTH SPOT NOISE (nV/√Hz OR pA/√Hz) – 3dB BANDWIDTH (MHz) RF = 470Ω AV = 2 RL = 10Ω –3dB BANDWIDTH (MHz) 80 100 10k PEAKING ≤ 1dB PEAKING ≤ 5dB AV = 2 RL = 100Ω FEEDBACK RESISTANCE (Ω) PEAKING ≤ 1dB PEAKING ≤ 5dB 90 0 Bandwidth and Feedback Resistance vs Capacitive Load for Peaking ≤ 1dB Bandwidth vs Supply Voltage Bandwidth vs Supply Voltage 5 7 11 13 9 SUPPLY VOLTAGE (±V) 15 1210 G08 – in 10 en +in 1 10 100 1k 10k FREQUENCY (Hz) 100k 1210 G09 5 LT1210 W U TYPICAL PERFOR A CE CHARACTERISTICS Supply Current vs Ambient Temperature, VS = ±5V Supply Current vs Supply Voltage 40 40 40 RSD = 0Ω 35 SUPPLY CURRENT (mA) TA = 25°C 36 TA = 85°C 34 32 30 TA = –40°C 28 TA = 125°C 26 AV = 1 RL = ∞ RSD = 0Ω 35 30 25 SUPPLY CURRENT (mA) 38 SUPPLY CURRENT (mA) Supply Current vs Ambient Temperature, VS = ±15V RSD = 7.5k 20 15 RSD = 15k 10 RSD = 0Ω 30 25 RSD = 47.5k 20 15 RSD = 82.5k 10 24 5 22 0 –50 –25 20 4 16 12 14 8 10 SUPPLY VOLTAGE (±V) 6 18 50 25 0 75 TEMPERATURE (°C) – 0.5 COMMON MODE RANGE (V) 35 SUPPLY CURRENT (mA) 3.0 OUTPUT SHORT-CIRCUIT CURRENT (A) VS = ±15V 20 15 10 5 –1.0 –1.5 –2.0 2.0 1.5 1.0 0.5 V– –50 0 100 300 400 200 SHUTDOWN PIN CURRENT (µA) 0 500 –25 0 25 50 75 TEMPERATURE (°C) 1210 G13 –3 –4 RL = 10Ω 4 3 2 RL = 2k 1 V– –50 –25 0 25 50 75 TEMPERATURE (°C) 100 125 1210 G16 6 2.2 2.0 1.8 50 25 75 0 TEMPERATURE (°C) 125 Supply Current vs Large-Signal Output Frequency (No Load) 100 60 NEGATIVE 50 100 1210 G15 70 RL = 2k RL = 10Ω –2 SINKING 2.4 1.6 –50 –25 125 RL = 50Ω VS = ±15V RF = RG = 1k POSITIVE 40 30 20 10 0 10k 90 SUPPLY CURRENT (mA) VS = ±15V SOURCING 2.6 Power Supply Rejection Ratio vs Frequency POWER SUPPLY REJECTION (dB) OUTPUT SATURATION VOLTAGE (V) –1 100 2.8 1210 G14 Output Saturation Voltage vs Junction Temperature 125 Output Short-Circuit Current vs Junction Temperature V+ 40 100 1210 G12 Input Common Mode Limit vs Junction Temperature 25 50 25 0 75 TEMPERATURE (°C) 1210 G11 Supply Current vs Shutdown Pin Current V+ 0 –50 –25 125 100 1210 G10 30 AV = 1 RL = ∞ 5 80 AV = 2 RL = ∞ VS = ±15V VOUT = 20VP-P 70 60 50 40 30 100k 1M 10M FREQUENCY (Hz) 100M 1210 G17 20 10k 100k 1M FREQUENCY (Hz) 10M 1210 G18 LT1210 W U TYPICAL PERFOR A CE CHARACTERISTICS Output Impedance in Shutdown vs Frequency Output Impedance vs Frequency 10k OUTPUT IMPEDANCE (Ω) 10 RSD = 82.5k RSD = 0Ω 1 0.1 0.01 100k 10M 1M FREQUENCY (Hz) 100M 18 LARGE-SIGNAL VOLTAGE GAIN (dB) VS = ±15V IO = 0mA 1k 100 10 1 100k 10M 1M FREQUENCY (Hz) 3rd Order Intercept vs Frequency 56 52 AV = 4, RL = 10Ω RF = 680Ω, RG = 220Ω VS = ±15V, VIN = 5VP-P 12 9 6 3 0 103 104 105 106 FREQUENCY (Hz) 107 108 1210 G21 Test Circuit for 3rd Order Intercept VS = ±15V RL = 10Ω RF = 680Ω RG = 220Ω 54 100M 15 1210 G20 1210 G19 3RD ORDER INTERCEPT (dBm) OUTPUT IMPEDANCE (Ω) 100 Large-Signal Voltage Gain vs Frequency + LT1210 50 PO – 48 680Ω 46 220Ω 44 10Ω MEASURE INTERCEPT AT PO 42 1210 TC01 40 0 2 4 6 FREQUENCY (MHz) 8 10 1210 G22 7 LT1210 U W U UO S I FOR ATIO The LT1210 is a current feedback amplifier with high output current drive capability. The device is stable with large capacitive loads and can easily supply the high currents required by capacitive loads. The amplifier will drive low impedance loads such as cables with excellent linearity at high frequencies. Feedback Resistor Selection The optimum value for the feedback resistors is a function of the operating conditions of the device, the load impedance and the desired flatness of response. The Typical AC Performance tables give the values which result in less than 1dB of peaking for various resistive loads and operating conditions. If this level of flatness is not required, a higher bandwidth can be obtained by use of a lower feedback resistor. The characteristic curves of Bandwidth vs Supply Voltage indicate feedback resistors for peaking up to 5dB. These curves use a solid line when the response has less than 1dB of peaking and a dashed line when the response has 1dB to 5dB of peaking. The curves stop where the response has more than 5dB of peaking. 14 VS = ±15V CL = 200pF 12 RF = 3.4k NO COMPENSATION 10 VOLTAGE GAIN (dB) APPLICATI 8 RF = 1.5k COMPENSATION 6 4 2 0 –2 RF = 3.4k COMPENSATION –4 –6 1 10 FREQUENCY (MHz) 100 1210 F01 Figure 1 tance. Also shown is the – 3dB bandwidth with the suggested feedback resistor vs the load capacitance. For resistive loads, the COMP pin should be left open (see Capacitive Loads section). Although the optional compensation works well with capacitive loads, it simply reduces the bandwidth when it is connected with resistive loads. For instance, with a 10Ω load, the bandwidth drops from 35MHz to 26MHz when the compensation is connected. Hence, the compensation was made optional. To disconnect the optional compensation, leave the COMP pin open. Capacitive Loads Shutdown/Current Set The LT1210 includes an optional compensation network for driving capacitive loads. This network eliminates most of the output stage peaking associated with capacitive loads, allowing the frequency response to be flattened. Figure 1 shows the effect of the network on a 200pF load. Without the optional compensation, there is a 6dB peak at 40MHz caused by the effect of the capacitance on the output stage. Adding a 0.01µF bypass capacitor between the output and the COMP pins connects the compensation and greatly reduces the peaking. A lower value feedback resistor can now be used, resulting in a response which is flat to ±1dB to 40MHz. The network has the greatest effect for CL in the range of 0pF to 1000pF. The graphs of Bandwidth and Feedback Resistance vs Capacitive Load can be used to select the appropriate value of feedback resistor. The values shown are for 1dB and 5dB peaking at a gain of 2 with no resistive load. This is a worst-case condition, as the amplifier is more stable at higher gains and with some resistive load in parallel with the capaci- If the shutdown feature is not used, the SHUTDOWN pin must be connected to ground or V –. 8 The Shutdown pin can be used to either turn off the biasing for the amplifier, reducing the quiescent current to less than 200µA, or to control the quiescent current in normal operation. The total bias current in the LT1210 is controlled by the current flowing out of the Shutdown pin. When the Shutdown pin is open or driven to the positive supply, the part is shut down. In the shutdown mode, the output looks like a 70pF capacitor and the supply current is typically less than 100µA. The Shutdown pin is referenced to the positive supply through an internal bias circuit (see the Simplified Schematic). An easy way to force shutdown is to use open-drain (collector) logic. The circuit shown in Figure 2 uses a 74C904 buffer to interface between 5V logic and the LT1210. The switching time between the active and shutdown states is about 1µs. A 24k pull-up resistor speeds LT1210 W U U UO APPLICATI S I FOR ATIO 15V VIN + VOUT LT1210 – SD response. The quiescent current can be reduced to 9mA in the inverting configuration without much change in response. In noninverting mode, however, the slew rate is reduced as the quiescent current is reduced. RF –15V 5V 74C906 RG 24k 15V ENABLE 1210 F02 Figure 2. Shutdown Interface RF = 750Ω RL = 10Ω IQ = 9mA, 18mA, 36mA VS = ±15V 1210 F04a Figure 4a. Large-Signal Response vs IQ, AV = –1 ENABLE VOUT up the turn-off time and ensures that the LT1210 is completely turned off. Because the pin is referenced to the positive supply, the logic used should have a breakdown voltage of greater than the positive supply voltage. No other circuitry is necessary as the internal circuit limits the Shutdown pin current to about 500µA. Figure 3 shows the resulting waveforms. RF = 750Ω RL = 10Ω AV = 1 RF = 825Ω RL = 50Ω RPULL-UP = 24k VIN = 1V P-P VS = ±15V 1210 F03 IQ = 9mA, 18mA, 36mA VS = ±15V 1210 F04b Figure 4b. Large-Signal Response vs IQ, AV = 2 Slew Rate Figure 3. Shutdown Operation For applications where the full bandwidth of the amplifier is not required, the quiescent current of the device may be reduced by connecting a resistor from the Shutdown pin to ground. The quiescent current will be approximately 65 times the current in the Shutdown pin. The voltage across the resistor in this condition is V + – 3VBE. For example, a 82k resistor will set the quiescent supply current to 9mA with VS = ±15V. The photos in Figures 4a and 4b show the effect of reducing the quiescent supply current on the large-signal Unlike a traditional op amp, the slew rate of a current feedback amplifier is not independent of the amplifier gain configuration. There are slew rate limitations in both the input stage and the output stage. In the inverting mode, and for higher gains in the noninverting mode, the signal amplitude on the input pins is small and the overall slew rate is that of the output stage. The input stage slew rate is related to the quiescent current and will be reduced as the supply current is reduced. The output slew rate is set by the value of the feedback resistors and the internal capacitance. Larger feedback resistors will reduce the slew rate as will lower supply voltages, similar to the way 9 LT1210 W U U UO APPLICATI S I FOR ATIO the bandwidth is reduced. The photos in Figures 5a, 5b and 5c show the large-signal response of the LT1210 for various gain configurations. The slew rate varies from 770V/µs for a gain of 1, to 1100V/µs for a gain of – 1. RF = 825Ω RL = 10Ω VS = ±15V When the LT1210 is used to drive capacitive loads, the available output current can limit the overall slew rate. In the fastest configuration, the LT1210 is capable of a slew rate of over 1V/ns. The current required to slew a capacitor at this rate is 1mA per picofarad of capacitance, so 10,000pF would require 10A! The photo (Figure 6) shows the large-signal behavior with CL = 10,000pF. The slew rate is about 150V/µs, determined by the current limit of 1.5A. 1210 F05a Figure 5a. Large-Signal Response, AV = 1 RF = RG = 3k RL = ∞ VS = ±15V 1210 F06 Figure 6. Large-Signal Response, CL = 10,000pF Differential Input Signal Swing RF = RG = 750Ω RL = 10Ω VS = ±15V 1210 F05b Figure 5b. Large-Signal Response, AV = –1 The differential input swing is limited to about ±6V by an ESD protection device connected between the inputs. In normal operation, the differential voltage between the input pins is small, so this clamp has no effect; however, in the shutdown mode the differential swing can be the same as the input swing. The clamp voltage will then set the maximum allowable input voltage. To allow for some margin, it is recommended that the input signal be less than ±5V when the device is shut down. Capacitance on the Inverting Input RF = RG = 750Ω RL = 10Ω VS = ±15V 1210 F05c Figure 5c. Large-Signal Response, AV = 2 10 Current feedback amplifiers require resistive feedback from the output to the inverting input for stable operation. Take care to minimize the stray capacitance between the output and the inverting input. Capacitance on the inverting input to ground will cause peaking in the frequency response (and overshoot in the transient response), but it does not degrade the stability of the amplifier. LT1210 U W U UO APPLICATI S I FOR ATIO Power Supplies The LT1210 will operate from single or split supplies from ±5V (10V total) to ±15V (30V total). It is not necessary to use equal value split supplies, however the offset voltage and inverting input bias current will change. The offset voltage changes about 500µV per volt of supply mismatch. The inverting bias current can change as much as 5µA per volt of supply mismatch, though typically the change is less than 0.5µA per volt. Power Supply Bypassing To obtain the maximum output and the minimum distortion from the LT1210, the power supply rails should be well bypassed. For example, with the output stage pouring 1A current peaks into the load, a 1Ω power supply impedance will cause a droop of 1V, reducing the available output swing by that amount. Surface mount tantalum and ceramic capacitors make excellent low ESR bypass elements when placed close to the chip. For frequencies above 100kHz, use 1µF and 100nF ceramic capacitors. If significant power must be delivered below 100kHz, capacitive reactance becomes the limiting factor. Larger ceramic or tantalum capacitors, such as 4.7µF, are recommended in place of the 1µF unit mentioned above. Inadequate bypassing is evidenced by reduced output swing and “distorted” clipping effects when the output is driven to the rails. If this is observed, check the supply pins of the device for ripple directly related to the output waveform. Significant supply modulation indicates poor bypassing. For surface mount devices heat sinking is accomplished by using the heat spreading capabilities of the PC board and its copper traces. Experiments have shown that the heat spreading copper layer does not need to be electrically connected to the tab of the device. The PCB material can be very effective at transmitting heat between the pad area attached to the tab of the device, and a ground or power plane layer either inside or on the opposite side of the board. Although the actual thermal resistance of the PCB material is high, the length/area ratio of the thermal resistance between the layer is small. Copper board stiffeners and plated through holes can also be used to spread the heat generated by the device. Tables 1 and 2 list thermal resistance for each package. For the TO-220 package, thermal resistance is given for junction-to-case only since this package is usually mounted to a heat sink. Measured values of thermal resistance for several different board sizes and copper areas are listed for each surface mount package. All measurements were taken in still air on 3/32" FR-4 board with 2 oz copper. This data can be used as a rough guideline in estimating thermal resistance. The thermal resistance for each application will be affected by thermal interactions with other components as well as board size and shape. Table 1. R Package, 7-Lead DD COPPER AREA TOPSIDE* BACKSIDE THERMAL RESISTANCE BOARD AREA (JUNCTION-TO-AMBIENT) 2500 sq. mm 2500 sq. mm 2500 sq. mm 25°C/W 1000 sq. mm 2500 sq. mm 2500 sq. mm 27°C/W 125 sq. mm 2500 sq. mm 35°C/W 2500 sq. mm *Tab of device attached to topside copper Thermal Considerations The LT1210 contains a thermal shutdown feature which protects against excessive internal (junction) temperature. If the junction temperature of the device exceeds the protection threshold, the device will begin cycling between normal operation and an off state. The cycling is not harmful to the part. The thermal cycling occurs at a slow rate, typically 10ms to several seconds, which depends on the power dissipation and the thermal time constants of the package and heat sinking. Raising the ambient temperature until the device begins thermal shutdown gives a good indication of how much margin there is in the thermal design. Table 2. Fused 16-Lead SO Package COPPER AREA TOPSIDE BACKSIDE 2500 sq. mm 1000 sq. mm 600 sq. mm 180 sq. mm 180 sq. mm 180 sq. mm 180 sq. mm 180 sq. mm 180 sq. mm 2500 sq. mm 2500 sq. mm 2500 sq. mm 2500 sq. mm 1000 sq. mm 600 sq. mm 300 sq. mm 100 sq. mm 0 sq. mm BOARD AREA THERMAL RESISTANCE (JUNCTION-TO-AMBIENT) 5000 sq. mm 3500 sq. mm 3100 sq. mm 2680 sq. mm 1180 sq. mm 780 sq. mm 480 sq. mm 280 sq. mm 180 sq. mm 40°C/W 46°C/W 48°C/W 49°C/W 56°C/W 58°C/W 59°C/W 60°C/W 61°C/W 11 LT1210 W U U UO APPLICATI S I FOR ATIO 5V T7 Package, 7-Lead TO-220 Thermal Resistance (Junction-to-Case) = 5°C/W 76mA A Calculating Junction Temperature The junction temperature can be calculated from the equation: + LT1210 – TJ = (PD)(θJA) + TA 2V 0V –2V VO SD 10Ω VO = 1.4VRMS where: TJ = Junction Temperature TA = Ambient Temperature PD = Device Dissipation θJA = Thermal Resistance (Junction-to-Ambient) –5V 220Ω 680Ω 1210 F07 Figure 7 then: As an example, calculate the junction temperature for the circuit in Figure 7 for the SO and R packages assuming a 70°C ambient temperature. The device dissipation can be found by measuring the supply currents, calculating the total dissipation and then subtracting the dissipation in the load and feedback network. TJ = (0.56W)(46°C/W) + 70°C = 96°C for the SO package with 1000 sq. mm topside heat sinking TJ = (0.56W)(27°C/W) + 70°C = 85°C for the R package with 1000 sq. mm topside heat sinking Since the maximum junction temperature is 150°C, both packages are clearly acceptable. PD = (76mA)(10V) – (1.4V)2/ 10 = 0.56W U TYPICAL APPLICATIONS Precision × 10 High Current Amplifier VIN CMOS Logic to Shutdown Interface 15V + + LT1097 LT1210 COMP – SD – + OUT LT1210 SD 0.01µF – 500pF 3k 330Ω 24k 5V –15V 10k 2N3904 9.09k OUTPUT OFFSET: < 500µV SLEW RATE: 2V/µs BANDWIDTH: 4MHz STABLE WITH CL < 10nF 12 1210 TA04 1k 1210 TA03 LT1210 U TYPICAL APPLICATIONS Buffer AV = 1 Distribution Amplifier + VIN 75Ω 75Ω + VIN 75Ω CABLE LT1210 COMP SD LT1210 SD – – 75Ω RF VOUT 0.01µF* 75Ω RF** * OPTIONAL, USE WITH CAPACITIVE LOADS ** VALUE OF R F DEPENDS ON SUPPLY VOLTAGE AND LOADING. SELECT FROM TYPICAL AC PERFORMANCE TABLE OR DETERMINE EMPIRICALLY RG 1210 TA06 75Ω 1210 TA05 W W SI PLIFIED SCHE ATIC V+ TO ALL CURRENT SOURCES Q5 Q10 Q2 Q18 D1 Q6 Q1 Q17 Q11 Q15 Q9 V– 1.25k +IN CC –IN V– 50Ω COMP RC OUTPUT V+ SHUTDOWN V+ Q12 Q3 Q8 Q16 Q14 D2 Q4 Q7 Q13 V– 1210 SS 13 LT1210 U PACKAGE DESCRIPTION Dimensions in inches (millimeters) unless otherwise noted. R Package 7-Lead Plastic DD Pak (LTC DWG # 05-08-1462) 0.256 (6.502) 0.060 (1.524) 0.060 (1.524) TYP 0.390 – 0.415 (9.906 – 10.541) 0.165 – 0.180 (4.191 – 4.572) 0.045 – 0.055 (1.143 – 1.397) 15° TYP 0.060 (1.524) 0.183 (4.648) 0.059 (1.499) TYP 0.330 – 0.370 (8.382 – 9.398) ( +0.203 0.102 –0.102 BOTTOM VIEW OF DD PAK HATCHED AREA IS SOLDER PLATED COPPER HEAT SINK ( +0.012 0.143 –0.020 +0.305 3.632 –0.508 0.040 – 0.060 (1.016 – 1.524) 0.026 – 0.036 (0.660 – 0.914) ) 0.013 – 0.023 (0.330 – 0.584) 0.050 ± 0.012 (1.270 ± 0.305) R (DD7) 0396 S Package 16-Lead Plastic Small Outline (Narrow 0.150) (LTC DWG # 05-08-1610) 0.386 – 0.394* (9.804 – 10.008) 16 15 14 13 12 11 10 9 0.150 – 0.157** (3.810 – 3.988) 0.228 – 0.244 (5.791 – 6.197) 1 0.010 – 0.020 × 45° (0.254 – 0.508) 0.008 – 0.010 (0.203 – 0.254) 2 3 4 5 0.053 – 0.069 (1.346 – 1.752) *DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE **DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE 0.014 – 0.019 (0.355 – 0.483) 6 7 8 0.004 – 0.010 (0.101 – 0.254) 0° – 8° TYP 0.016 – 0.050 0.406 – 1.270 14 ) 0.095 – 0.115 (2.413 – 2.921) 0.075 (1.905) 0.300 (7.620) +0.008 0.004 –0.004 0.050 (1.270) TYP S16 0695 LT1210 U PACKAGE DESCRIPTION Dimensions in inches (millimeters) unless otherwise noted. T7 Package 7-Lead Plastic TO-220 (Standard) (LTC DWG # 05-08-1422) 0.390 – 0.415 (9.906 – 10.541) 0.165 – 0.180 (4.293 – 4.572) 0.147 – 0.155 (3.734 – 3.937) DIA 0.045 – 0.055 (1.143 – 1.397) 0.230 – 0.270 (5.842 – 6.858) 0.460 – 0.500 (11.684 – 12.700) 0.570 – 0.620 (14.478 – 15.748) 0.330 – 0.370 (8.382 – 9.398) 0.620 (15.75) TYP 0.700 – 0.728 (17.780 – 18.491) 0.152 – 0.202 0.260 – 0.320 (3.860 – 5.130) (6.604 – 8.128) 0.040 – 0.060 (1.016 – 1.524) 0.095 – 0.115 (2.413 – 2.921) 0.013 – 0.023 (0.330 – 0.584) 0.026 – 0.036 (0.660 – 0.914) 0.135 – 0.165 (3.429 – 4.191) 0.155 – 0.195 (3.937 – 4.953) T7 (TO-220) (FORMED) 0695 Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. 15 LT1210 U TYPICAL APPLICATION Wideband 9W Bridge Amplifier 15V INPUT 5VP-P Frequency Response + LT1210 SD – PO 9W 26 T1* 10nF 1 RL 50Ω 9W 23 20 1 17 GAIN (dB) 680Ω –15V 1 100nF 220Ω 910Ω + LT1210 SD – 11 8 5 1 15V 14 1 1 2 –1 –4 10k 100k 10nF 1M 10M FREQUENCY (Hz) 100M 1210 TA08 * COILTRONICS Versa-PacTM CTX-01-13033-X2 OR EQUIVALENT 1210 TA07 –15V Versa-Pac is a trademark of Coiltronics, Inc. RELATED PARTS PART NUMBER DESCRIPTION COMMENTS LT1010 Fast ±150mA Power Buffer 20MHz Bandwidth, 75V/µs Slew Rate LT1166 Power Output Stage Automatic Bias System Sets Class AB Bias Currents for High Voltage/High Power Output Stages LT1206 Single 250mA, 60MHz Current Feedback Amplifier Shutdown Function, Stable with CL = 10,000pF, 900V/µs Slew Rate LT1207 Dual 250mA, 60MHz Current Feedback Amplifier Dual Version of LT1206 LT1227 Single 140MHz Current Feedback Amplifier Shutdown Function, 1100V/µs Slew Rate LT1360 Single 50MHz, 800V/µs Op Amp Voltage Feedback, Stable with CL = 10,000pF LT1363 Single 70MHz, 1000V/µs Op Amp Voltage Feedback, Stable with CL = 10,000pF 16 Linear Technology Corporation LT/GP 0796 7K • PRINTED IN USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● TELEX: 499-3977 LINEAR TECHNOLOGY CORPORATION 1996