LM3301N

LM2900 LM3900 LM3301 Quad Amplifiers February 1995 LM2900 LM3900 LM3301 Quad Amplifiers General Description The LM2900 series consists of four independent dual input internally compensated amplifiers which were designed specifically to operate off of a single power supply voltage and to provide a large output voltage swing These amplifiers make use of a current mirror to achieve the non-inverting input function Application areas include ac amplifiers RC active filters low frequency triangle squarewave and pulse waveform generation circuits tachometers and low speed high voltage digital logic gates Features Y Y Y Y Y Y Y Y Wide single supply voltage 4 VDC to 32 VDC g 2 VDC to g 16 VDC Range or dual supplies Supply current drain independent of supply voltage Low input biasing current 30 nA High open-loop gain 70 dB Wide bandwidth 2 5 MHz (unity gain) a Large output voltage swing (V b 1) Vp-p Internally frequency compensated for unity gain Output short-circuit protection Schematic and Connection Diagrams Dual-In-Line and S O TL H 7936 – 2 Top View Order Number LM2900N LM3900M LM3900N or LM3301N See NS Package Number M14A or N14A TL H 7936 – 1 C1995 National Semiconductor Corporation TL H 7936 RRD-B30M115 Printed in U S A Absolute Maximum Ratings If Military Aerospace specified devices are required please contact the National Semiconductor Sales Office Distributors for availability and specifications LM2900 LM3900 LM3301 Supply Voltage 32 VDC 28 VDC g 16 VDC g 14 VDC Power Dissipation (TA e 25 C) (Note 1) Molded DIP 1080 mW 1080 mW S O Package 765 mW a b Input Currents IIN or IIN 20 mADC 20 mADC Output Short-Circuit Duration One Amplifier Continuous Continuous TA e 25 C (See Application Hints) b 40 C to a 85 C Operating Temperature Range b 40 C to a 85 C LM2900 LM3900 0 C to a 70 C b 65 C to a 150 C b 65 C to a 150 C Storage Temperature Range 260 C Lead Temperature (Soldering 10 sec ) 260 C Soldering Information Dual-In-Line Package Soldering (10 sec ) 260 C 260 C Small Outline Package Vapor Phase (60 sec ) 215 C 215 C Infrared (15 sec ) 220 C 220 C See AN-450 ‘‘Surface Mounting Methods and Their Effect on Product Reliability’’ for other methods of soldering surface mount devices ESD tolerance (Note 7) 2000V 2000V Electrical Characteristics TA e 25 C Parameter Open Loop Voltage Gain Voltage Gain Input Resistance Output Resistance Unity Gain Bandwidth Input Bias Current Slew Rate Supply Current Output Voltage Swing VOUT High VOUT Low VOUT High V e Absolute Maximum Ratings a V a e 15 VDC unless otherwise stated LM2900 Conditions Min Over Temp DVO e 10 VDC Inverting Input Typ Max Min LM3900 Typ Max Min LM3301 Units Typ Max V mV MX kX MHz 300 nA V ms 10 mADC 12 28 1 8 12 28 1 8 25 12 28 1 9 25 Inverting Input Inverting Input V Inverting Input a 25 e 5 VDC 30 05 20 62 13 5 0 09 200 30 05 20 200 30 05 20 Positive Output Swing Negative Output Swing RL e % On All Amplifiers RL e 2k a V e 15 0 VDC b IIN e 0 IIN a e 0 b IIN e 10 mA a IIN e 0 10 13 5 02 62 10 13 5 62 0 09 02 0 09 02 VDC IIN e 0 a IIN e 0 RL e % b 29 5 6 18 13 5 29 5 6 05 10 13 5 26 0 5 05 18 13 5 mADC Output Source Current Sink Capability ISINK (Note 2) b VOL e 1V IIN e 5 mA 05 2 Electrical Characteristics (Note 6) Parameter Power Supply Rejection Mirror Gain DMirror Gain Mirror Current Negative Input Current Input Bias Current Conditions V a e 15 VDC unless otherwise stated (Continued) LM2900 Min TA e 25 C f e 100 Hz 20 mA (Note 3) 200 mA (Note 3) 20 mA to 200 mA (Note 3) (Note 4) TA e 25 C (Note 5) Inverting Input 0 90 0 90 Typ 70 10 10 2 10 10 300 11 11 5 500 0 90 0 90 Max Min LM3900 Typ 70 10 10 2 10 10 300 11 11 5 500 0 90 0 90 Max Min LM3301 Units Typ 70 1 1 2 10 10 1 10 1 10 5 500 Max dB mA mA % mADC mADC nA Note 1 For operating at high temperatures the device must be derated based on a 125 C maximum junction temperature and a thermal resistance of 92 C W which applies for the device soldered in a printed circuit board operating in a still air ambient Thermal resistance for the S O package is 131 C W Note 2 The output current sink capability can be increased for large signal conditions by overdriving the inverting input This is shown in the section on Typical Characteristics Note 3 This spec indicates the current gain of the current mirror which is used as the non-inverting input Note 4 Input VBE match between the non-inverting and the inverting inputs occurs for a mirror current (non-inverting input current) of approximately 10 mA This is therefore a typical design center for many of the application circuits Note 5 Clamp transistors are included on the IC to prevent the input voltages from swinging below ground more than approximately b 0 3 VDC The negative input currents which may result from large signal overdrive with capacitance input coupling need to be externally limited to values of approximately 1 mA Negative input currents in excess of 4 mA will cause the output voltage to drop to a low voltage This maximum current applies to any one of the input terminals If more than one of the input terminals are simultaneously driven negative smaller maximum currents are allowed Common-mode current biasing can be used to prevent negative input voltages see for example the ‘‘Differentiator Circuit’’ in the applications section Note 6 These specs apply for b 40 C s TA s a 85 C unless otherwise stated Note 7 Human body model 1 5 kX in series with 100 pF Application Hints When driving either input from a low-impedance source a limiting resistor should be placed in series with the input lead to limit the peak input current Currents as large as 20 mA will not damage the device but the current mirror on the non-inverting input will saturate and cause a loss of mirror gain at mA current levels especially at high operating temperatures Precautions should be taken to insure that the power supply for the integrated circuit never becomes reversed in polarity or that the unit is not inadvertently installed backwards in a test socket as an unlimited current surge through the resulting forward diode within the IC could cause fusing of the internal conductors and result in a destroyed unit Output short circuits either to ground or to the positive power supply should be of short time duration Units can be destroyed not as a result of the short circuit current causing metal fusing but rather due to the large increase in IC chip dissipation which will cause eventual failure due to excessive junction temperatures For example when operating from a well-regulated a 5 VDC power supply at TA e 25 C with a 100 kX shunt-feedback resistor (from the output to the inverting input) a short directly to the power supply will not cause catastrophic failure but the current magnitude will be approximately 50 mA and the junction temperature will be above TJ max Larger feedback resistors will reduce the current 11 MX provides approximately 30 mA an open circuit provides 1 3 mA and a direct connection from the output to the non-inverting input will result in catastrophic faila ure when the output is shorted to V as this then places the base-emitter junction of the input transistor directly across the power supply Short-circuits to ground will have magnitudes of approximately 30 mA and will not cause catastrophic failure at TA e 25 C Unintentional signal coupling from the output to the non-inverting input can cause oscillations This is likely only in breadboard hook-ups with long component leads and can be prevented by a more careful lead dress or by locating the non-inverting input biasing resistor close to the IC A quick check of this condition is to bypass the non-inverting input to ground with a capacitor High impedance biasing resistors used in the non-inverting input circuit make this input lead highly susceptible to unintentional AC signal pickup Operation of this amplifier can be best understood by noticing that input currents are differenced at the inverting-input terminal and this difference current then flows through the external feedback resistor to produce the output voltage Common-mode current biasing is generally useful to allow operating with signal levels near ground or even negative as this maintains the inputs biased at a VBE Internal clamp transistors (see note 5) catch-negative input voltages at approximately b0 3 VDC but the magnitude of current flow has to be limited by the external input network For operation at high temperature this limit should be approximately 100 mA This new ‘‘Norton’’ current-differencing amplifier can be used in most of the applications of a standard IC op amp Performance as a DC amplifier using only a single supply is not as precise as a standard IC op amp operating with split supplies but is adequate in many less critical applications New functions are made possible with this amplifier which are useful in single power supply systems For example biasing can be designed separately from the AC gain as was shown in the ‘‘inverting amplifier ’’ the ‘‘difference integrator’’ allows controlling the charging and the discharging of the integrating capacitor with positive voltages and the ‘‘frequency doubling tachometer’’ provides a simple circuit which reduces the ripple voltage on a tachometer output DC voltage 3 Typical Performance Characteristics Open Loop Gain Voltage Gain Voltage Gain Input Current Supply Current Large Signal Frequency Response Output Sink Current Output Class-A Bias Current Output Source Current Supply Rejection Mirror Gain Maximum Mirror Current TL H 7936 – 9 4 Typical Applications (V a e 15 VDC) Inverting Amplifier Triangle Square Generator VODC e AV j b V 2 a R2 R1 TL H 7936– 3 TL H 7936 – 4 Frequency-Doubling Tachometer Low VIN b VOUT Voltage Regulator TL H 7936 – 5 TL H 7936 – 6 Non-Inverting Amplifier Negative Supply Biasing VODC e AV j V 2 a R2 R1 TL H 7936 – 7 VODC e AV j R2 b V R3 TL H 7936 – 8 R2 R1 5 Typical Applications (V a e 15 VDC) (Continued) Low-Drift Ramp and Hold Circuit TL H 7936 – 10 Bi-Quad Active Filter (2nd Degree State-Variable Network) Q e 50 fO e 1 kHz TL H 7936 – 11 6 Typical Applications (V a e 15 VDC) (Continued) Voltage-Controlled Current Source (Transconductance Amplifier) TL H 7936 – 12 Hi VIN Lo (VIN b VO) Self-Regulator Q1 Q2 absorb Hi VIN TL H 7936 – 13 Ground-Referencing a Differential Input Signal TL H 7936 – 14 7 Typical Applications (V a e 15 VDC) (Continued) Voltage Regulator Fixed Current Sources (VO e VZ a VBE) TL H 7936–15 I2 e R1 I1 R2 TL H 7936 – 16 Voltage-Controlled Current Sink (Transconductance Amplifier) Buffer Amplifier VIN t VBE TL H 7936 – 18 TL H 7936 – 17 Tachometer VODC e A fIN TL H 7936 – 19 Allows VO to go to zero 8 Typical Applications (V a e 15 VDC) (Continued) Low-Voltage Comparator No negative voltage limit if properly biased Power Comparator TL H 7936 – 20 TL H 7936 – 21 Comparator Schmitt-Trigger TL H 7936 – 22 TL H 7936 – 23 Square-Wave Oscillator Pulse Generator TL H 7936 – 24 TL H 7936 – 25 Frequency Differencing Tachometer VODC e A (f1 b f2) TL H 7936 – 26 9 Typical Applications (V a e 15 VDC) (Continued) Frequency Averaging Tachometer VODC e A (f1 a f2) TL H 7936 – 27 Squaring Amplifier (W Hysteresis) Bi-Stable Multivibrator TL H 7936 – 29 TL H 7936–28 Differentiator (Common-Mode Biasing Keeps Input at a VBE) ‘‘OR’’ Gate feAaBaC TL H 7936 – 31 AV e 1 2 TL H 7936 – 30 ‘‘AND’’ Gate Difference Integrator feABC TL H 7936–32 TL H 7936 – 33 10 Typical Applications (V a e 15 VDC) (Continued) Low Pass Active Filter fO e 1 kHz TL H 7936 – 34 Staircase Generator VBE Biasing AV j b TL H 7936 – 35 R2 R1 TL H 7936 – 36 Bandpass Active Filter fo e 1 kHz Q e 25 TL H 7936 – 37 11 Typical Applications (V a e 15 VDC) (Continued) Low-Frequency Mixer TL H 7936 – 38 Free-Running Staircase Generator Pulse Counter TL H 7936 – 39 12 Typical Applications (V a e 15 VDC) (Continued) Supplying IIN with Aux Amp (to Allow Hi-Z Feedback Networks) TL H 7936 – 40 One-Shot Multivibrator PW j 2 c 106C Speeds recovery TL H 7936 – 41 Non-Inverting DC Gain to (0 0) TL H 7936 – 42 13 Typical Applications (V a e 15 VDC) (Continued) Channel Selection by DC Control (or Audio Mixer) TL H 7936 – 43 14 Typical Applications (V a e 15 VDC) (Continued) Power Amplifier TL H 7936 – 44 One-Shot with DC Input Comparator a Trips at VIN j 0 8 V VIN must fall 0 8 V a prior to t2 TL H 7936 – 45 High Pass Active Filter TL H 7936 – 46 15 Typical Applications (V a e 15 VDC) (Continued) Sample-Hold and Compare with New a VIN TL H 7936 – 47 Sawtooth Generator TL H 7936 – 48 16 Typical Applications (V a e 15 VDC) (Continued) Phase-Locked Loop TL H 7936 – 49 Boosting to 300 mA Loads TL H 7936 – 50 17 Split-Supply Applications (V a e a 15 VDC V b e b 15 VDC) Non-Inverting DC Gain TL H 7936 – 51 AC Amplifier TL H 7936 – 52 18 Physical Dimensions inches (millimeters) Small Outline Package (M) Order Number LM3900M NS Package Number M14A 19 LM2900 LM3900 LM3301 Quad Amplifiers Physical Dimensions inches (millimeters) (Continued) Molded Dual-In-Line Package (N) Order Number LM2900N LM3900N or LM3301N NS Package Number N14A LIFE SUPPORT POLICY NATIONAL’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 NATIONAL SEMICONDUCTOR CORPORATION 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 National Semiconductor Corporation 1111 West Bardin Road Arlington TX 76017 Tel 1(800) 272-9959 Fax 1(800) 737-7018 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 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