8001401ZX

ISO 9001 CERTIFIED BY DSCC M.S.KENNEDY CORP. FEATURES: FET INPUT HIGH SPEED VOLTAGE FOLLOWER/BUFFER AMPLIFIER 0033 (315) 701-6751 4707 Dey Road Liverpool, N.Y. 13088 Industry Wide LH0033/EL2005 Replacement Low Input Offset - 2mV Low Input Offset Drift - 25µV/°C FET Input, Low Input Current - 50pA High Slew Rate - 1500V/µS Wide Bandwidth - 140MHz High Output Current - ±100mA Available to DSCC SMD 5962-80014 MIL-PRF-38534 CERTIFIED DESCRIPTION: The MSK 0033(B) is a high speed, wide bandwidth voltage follower/buffer amplifier that is pin compatible with all other 0033 designs. The FET input is cascaded to force the input characteristics to remain constant over the full input voltage range. Significantly improved performance in sample and hold circuits is achieved since the DC bias current remains constant with input voltage. The FET input also makes the MSK 0033 very accurate since it produces extremely low input bias current, input offset voltage and input offset voltage drift specifications. Transistion times in the range of 2.5 nS make the MSK 0033 fast enough for most high speed voltage follower/buffer amplifier applications. EQUIVALENT SCHEMATIC TYPICAL APPLICATIONS Sample And Hold Impedance Buffers For A to D's High Speed Line Drivers CRT Deflection Driver 1 2 3 4 5 6 PIN-OUT INFORMATION Positive Driver Power Supply N/C N/C N/C Input Offset Preset 1 7 8 9 10 11 12 Offset Adjust N/C Negative Driver Power Supply Negative Power Supply Output Positive Power Supply Rev. B 7/00 ABSOLUTE MAXIMUM RATINGS ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ELECTRICAL SPECIFICATIONS Parameter STATIC Supply Voltage Range Quiescent Current INPUT Offset Voltage Offset Voltage Drift Offset Adjust Input Bias Current 9 Input Impedance 3 Power Supply Rejection Ratio 2 Input Noise Density 3 Input Noise Voltage 3 OUTPUT Output Voltage Swing Output Current Settling Time to 1% 2 3 Bandwidth (-3dB) 3 TRANSFER CHARACTERISTICS Slew Rate Voltage Gain VOUT=±10V RS=100Ω VIN=1VRMS F=1KHz 4 4 1000 0.97 1500 0.99 1000 0.95 1500 0.98 V/µS V/V VIN=±14V RL=1KΩ VIN=±10.5V RL=100Ω 2V step VIN=1VRMS RL=1KΩ 4 4 ±12 ±90 ±12.5 ±110 25 140 ±12 ±90 ±12.5 ±110 25 140 V mA nS MHz Short Pin 6 to Pin 7 VIN=0V Short Pin 6 to Pin 7 VIN=0V Pin 6=open RPOT=200Ω From Pin 7 to Pin 9 VCM=0V Either Input F=DC ±10V≤VS≤±20V F=10Hz to 1KHz F=1KHz 1 2,3 1,2,3 1 2,3 65 ±2.0 ±25 ±50 ±2 10 75 1.5 40 12 Test Conditions Group A Subgroup - MSK 0033B Min. ±10 Typ. ±15 ±19 Max. ±18 ±22 ±10 ±250 ±100 ±10 Min. ±10 60 - MSK 0033 Typ. ±15 ±19 ±5 Adjust to Zero ±50 ±2 10 75 1.5 40 12 Max. ±18 ±25 ±15 ±500 - 38 VIN=0V 1 Adjust to Zero NOTES: Unless otherwise specified ±VCC = ±15 VDC. Measured within a high speed amplifier feedback loop. Devices shall be capable of meeting the parameter, but need not be tested. Typical parameters are for reference only. Industrial grade devices shall be tested to subgroups 1 and 4 unless otherwise specified. Military grade devices ('B' suffix) shall be 100% tested to subgroups 1,2,3 and 4. Subgroup 5 and 6 testing available upon request. Subgroup 1,4 TA=TC=+25°C Subgroup 2,5 TA=TC=+125°C Subgroup 3,6 TA=TC=-55°C 8 Electrical specifications are derated for power supply voltages other than ±15VDC. 9 Measurement made 0.5 seconds after application of power. Actual DC continuous test limit is 2.5 nA at 25°C 1 2 3 4 5 6 7 2 Rev. B 7/00 ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ TJ RTH ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ ±VCC IOUT VIN TC Supply Voltage ±20V Output Current ±120mA Differential Input Voltage ±20V Case Operating Temperature (MSK 0033B) -55°C to +125°C (MSK 0033) -40°C to +85°C ○ ○ ○ TST TLD Storage Temperature Range -65°C to +150°C Lead Temperature Range 300°C (10 Seconds) Junction Temperature 175°C Thermal Resistance 65°C/W Junction to Case Output Devices Only Units V mA mV µV/°C mV pA nA Ω dB µVRMS nV/√Hz APPLICATION NOTES HEAT SINKING To determine if a heat sink is necessary for your application and if so, what type, refer to the thermal model and governing equation below. RθSA = ((TJ - TA)/PD) - (RθJC) - (RθCS) = ((125°C - 80°C) / .64W) - 65°C/W - .15°C/W = 70.3 - 65.15 = 5.2°C/W The heat sink in this example must have a thermal resistance of no more than 5.2°C/W to maintain a junction temperature of no more than +125°C. Thermal Model: OFFSET VOLTAGE ADJUST See Figure 1. To externally null the offset voltage, connect a 200Ω potentiometer between Pins 7 and 10 and leave Pin 6 open. If offset null is not necessary, short Pin 6 to Pin 7 and remove the 200Ω potentiometer. Do not connect Pin 7 to Vcc. Governing Equation: TJ=PD x (RθJC + RθCS + RθSA) + TA Where TJ = Junction Temperature PD = Total Power Dissipation RθJC = Junction to Case Thermal Resistance RθCS = Case to Heat Sink Thermal Resistance RθSA = Heat Sink to Ambient Thermal Resistance TC = Case Temperature TA = Ambient Temperature TS = Sink Temperature Example: This example demonstrates a worst case analysis for the buffer output stage. This occurs when the output voltage is 1/2 the power supply voltage. Under this condition, maximum power transfer occurs and the output is under maximum stress. Conditions: VCC = ±16VDC VO = ±8Vp Sine Wave, Freq. = 1KHz RL = 100Ω For a worst case analysis we will treat the ±8Vp sine wave as an 8 VDC output voltage. 1.) Find Driver Power Dissipation PD = (VCC-VO) (VO/RL) = (16V-8V) (8V/100Ω) = 640mW 2.) For conservative design, set TJ=+125°C Max. 3.) For this example, worst case TA=+80°C 4.) RθJC = 65°C/W from MSK 0033B Data Sheet 5.) RθCS = 0.15°C/W for most thermal greases 6.) Rearrange governing equation to solve for RθSA CURRENT LIMITING See Figure 1. If no current limit is required, short Pin 1 to Pin 12 and Pin 9 to Pin 10 and delete Q1 thru Q4 connections. Q1 through Q4 and the Rlim resistors form a current source current limit scheme and current limit resistor values can be calculated as follows: +Rlim ≅ Vbe -Rlim ≅ Vbe Isc Isc Since current limit is directly proportional to the base-emitter voltage drop of the 2N2222's and 2N2907's in the current limit scheme, the current limit value will change slightly with ambient temperature changes. The base-emitter voltage drop will decrease as temperature increases causing the actual current limit point to decrease. POWER SUPPLY BYPASSING Both the negative and the positive power supplies must be effectively decoupled with a high and low frequency bypass circuit to avoid power supply induced oscillation. An effective decoupling scheme consists of a 0.1 microfarad ceramic capacitor in parallel with a 4.7 microfarad tantalum capacitor from each power supply pin to ground. 3 Rev. B 7/00 TYPICAL APPLICATIONS 4 Rev. B 7/00 TYPICAL PERFORMANCE CURVES 5 Rev. B 7/00 MECHANICAL SPECIFICATIONS TO-8 BOTTOM VIEW ALL DIMENSIONS ARE ±0.010 INCHES UNLESS OTHERWISE LABELED ORDERING INFORMATION Part Number MSK0033 MSK0033B 8001401ZX Screening Level Industrial Military-Mil-PRF-38534 DSCC - SMD 4707 Dey Road, Liverpool, New York 13088 Phone (315) 701-6751 FAX (315) 701-6752 www.mskennedy.com The information contained herein is believed to be accurate at the time of printing. MSK reserves the right to make changes to its products or specifications without notice, however, and assumes no liability for the use of its products. M.S. Kennedy Corp. 6 Rev. B 7/00