HA-5002/883 Data Sheet January 5, 2006 FN3705.4 Monolithic, Wideband, High Slew Rate, Features High Output Current Buffer This Circuit is Processed in Accordance to MIL-STD-883 The HA-5002/883 is a monolithic, wideband, high slew rate, and is Fully Conformant Under the Provisions of Paragraph 1.2.1. high output current, buffer amplifier. Voltage Gain (R = 1k) 0.98 (Min) Utilizing the advantages of the Intersil Dielectric Isolation L 0.995 (Typ) technologies, the HA-5002/883 current buffer offers 1300V/s slew rate typically and 1000V/s minimum with (R = 100) . 0.96 (Min) L 110MHz of bandwidth. The 100mA minimum output current 0.971 (Typ) capability is enhanced by a 3 output impedance. High Input Impedance 1.5M (Min) The monolithic HA-5002/883 will replace the hybrid LH0002 3M (Typ) with corresponding performance increases. These Low Output Impedance . 5 (Max) characteristics range from the 3M (typ) input impedance to 3 (Typ) the increased output voltage swing. Monolithic design technologies have allowed a more precise buffer to be Very High Slew Rate .1000V/s (Min) 1300V/s (Typ) developed with more than an order of magnitude smaller gain error. The voltage gain is 0.98 guaranteed minimum Wide Small Signal Bandwidth .110MHz (Typ) with a 1k load and 0.96 minimum with a 100 load. High Output Current 100mA (Min) The HA-5002/883 will provide many present hybrid users High Pulsed Output Current . 400mA (Max) with a higher degree of reliability and at the same time increase overall circuit performance. Monolithic Dielectric Isolation Construction Replaces Hybrid LH0002 Ordering Information Applications TEMP PART PART RANGE Line Driver NUMBER MARKING (C) PACKAGE Data Acquisition HA2-5002/883 HA2-5002/883 -55 to +125 8 Pin Can HA4-5002/883 HA4-5002/883 -55 to +125 20 Ld Ceramic LCC 110MHz Buffer High Power Current Booster High Power Current Source Sample and Holds Radar Cable Driver Video Products Pinouts HA-5002/883 (CLCC) HA-5002/883 TOP VIEW (METAL CAN) TOP VIEW IN 3 2 1 20 19 8 18 NC 4 NC V + V - 1 1 7 1 17 V + V - 5 2 2 16 NC NC 6 V + V - 2 6 2 2 15 NC NC 7 NC 14 NC 8 NC 3 5 NC 13 910 11 12 4 OUT CAUTION: These devices are sensitive to electrostatic discharge follow proper IC Handling Procedures. 1 1-888-INTERSIL or 1-888-468-3774 Intersil (and design) is a registered trademark of Intersil Americas Inc. Copyright Intersil Americas Inc. 2002, 2004-2006. All Rights Reserved All other trademarks mentioned are the property of their respective owners. NC NC IN V + 1 NC NC V - OUT 1 NC NCHA-5002/883 Absolute Maximum Ratings Thermal Information Voltage Between V+ and V- Terminals .44V Thermal Resistance (C/W) (C/W) JA JC Input Voltage . Equal to Supplies Metal Can Package . 160 70 Peak Output Current (50ms On, 1s Off) 400mA Ceramic LCC Package . 80 30 Junction Temperature (T ) .+175C J Package Power Dissipation Limit at +75C for T +175C J Storage Temperature Range -65C to +150C Metal Can Package 625mW ESD Rating <4000V Ceramic LCC Package .1.25W Lead Temperature (Soldering 10s) +300C Package Power Dissipation Derating Factor Above +75C Metal Can Package 6.3mW/C Operating Conditions Ceramic LCC Package .12.5mW/C Operating Temperature Range -55C to +125C Operating Supply Voltage . 12V to 15V R 100 L CAUTION: Stresses above those listed in Absolute Maximum Ratings may cause permanent damage to the device. This is a stress only rating and operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. NOTE: 1. is measured with the component mounted on a low effective thermal conductivity test board in free air. See Tech Brief TB379 JA for details. TABLE 1. DC ELECTRICAL PERFORMANCE CHARACTERISTICS Device Tested at: V = 12V and 15V, R = 50, C 10pF, V = 0V, Unless Otherwise Specified. SUPPLY SOURCE LOAD IN GROUP A PARAMETERS SYMBOL CONDITIONS SUBGROUPS TEMPERATURE (C) MIN MAX UNITS Input Offset V V = 15V 1 +25 -20 20 mV IO1 SUP Voltage 2, 3 +125, -55 -30 30 mV V V = 12V 1 +25 -20 20 mV IO2 SUP 2, 3 +125, -55 -30 30 mV Input Bias Current I V = 15V, R = 1k 1+25 -7 7 A B1 SUP S 2, 3 +125, -55 -10 10 A I V = 12V, R = 1k 1+25 -7 7 A B2 SUP S 2, 3 +125, -55 -10 10 A Voltage Gain 1 +AV V = 12V, R = 1k, 1 +25 0.98 - V/V 1 SUP L V = 10V IN 2, 3 +125, -55 0.98 - V/V -AV V = 12V, R = 1k, 1 +25 0.98 - V/V 1 SUP L V = -10V IN 2, 3 +125, -55 0.98 - V/V Voltage Gain 2 +AV V = 12V, R = 100, 1 +25 0.96 - V/V 2 SUP L V = 10V IN -AV V = 12V, R = 100, 1 +25 0.96 - V/V 2 SUP L V = -10V IN Voltage Gain 3 +AV V = 15V, R = 100, 1 +25 0.96 - V/V 3 SUP L V = 10V IN -AV V = 15V, R = 100, 1 +25 0.96 - V/V 3 SUP L V = -10V IN Voltage Gain 4 +AV V = 15V, 1 +25 0.99 - V/V 4 SUP R = 1k, L 2, 3 +125, -55 0.99 - V/V V = +10V IN -AV V = 15V, 1 +25 0.99 - V/V 4 SUP R = 1k, L 2, 3 +125, -55 0.99 - V/V V = -10V IN FN3705.4 2 January 5, 2006