LME49860NA National Semiconductor, LME49860NA Datasheet

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... Power Supply Voltage Range ■  THD 1kHz) V OUT RMS IN Typical Application © 2007 National Semiconductor Corporation R = 2kΩ 600Ω ■  Input Noise Density ■  Slew Rate ■  Gain Bandwidth Product ■  ...

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... L49860 — LME49860 MA — Package code www.national.com Order Number LME49860MA See NS Package Number — M08A Order Number LME49860NA See NS Package Number — N08E LME49860NA Top Mark 20215101 U — Fabrication code Z — Assembly Plant code XY — 2 Digit Date code TT — Die Traceability 2 ...

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... Absolute Maximum Ratings If Military/Aerospace specified devices are required, please contact the National Semiconductor Sales Office/ Distributors for availability and specifications. Power Supply Voltage ( Storage Temperature   Input Voltage (V-) Output Short Circuit (Note 3) ESD Susceptibility (Note 4) ESD Susceptibility (Note 5) Pins and 8 Electrical Characteristics for the LME49860 ± ...

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Symbol Parameter CMRR Common-Mode Rejection Differential Input Impedance Z IN Common Mode Input Impedance A Open Loop Voltage Gain VOL V Maximum Output Voltage Swing OUTMAX I Output Current OUT I Instantaneous Short Circuit Current OUT-CC R Output Impedance OUT ...

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Typical Performance Characteristics THD+N vs Output Voltage V = 15V –15V 2kΩ L THD+N vs Output Voltage V = 22V –22V 2kΩ L THD+N vs Output Voltage V ...

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THD+N vs Output Voltage V = 22V 600Ω THD+N vs Output Voltage V = 15V 10kΩ L THD+N vs Output Voltage V = 22V ...

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THD+N vs Frequency V = 15V –15V OUT RMS R = 2kΩ L 20215163 THD+N vs Frequency V = 22V –22V OUT RMS R = 2kΩ ...

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THD+N vs Frequency V = 15V –15V 10kΩ L THD+N vs Frequency V = 22V –22V 10kΩ L IMD vs Output Voltage V = 12V, V ...

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IMD vs Output Voltage V = 2.5V –2. 2kΩ L 202151e4 IMD vs Output Voltage V = 12V –12V 600Ω 202151e0 IMD vs Output Voltage V = ...

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IMD vs Output Voltage V = 12V 10kΩ L IMD vs Output Voltage V = 2.5V 10kΩ L Current Noise Density vs Frequency www.national.com = –12V 202151f0 = –2.5V 202151l6 ...

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Crosstalk vs Frequency V = 15V –15V 10V CC EE OUT RMS A = 0dB 2kΩ 202151c9 Crosstalk vs Frequency V = 12V –12V 10V CC EE OUT ...

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Crosstalk vs Frequency V = 15V –15V 0dB Crosstalk vs Frequency V = 12V –12V 0dB Crosstalk vs Frequency V ...

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Crosstalk vs Frequency V = 2.5V –2.5V OUT RMS = 600Ω 0dB 202151d2 Crosstalk vs Frequency V = 15V –15V 10V CC EE OUT ...

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Crosstalk vs Frequency V = 22V –22V 0dB PSRR+ vs Frequency V = 15V 2kΩ RIPPLE PSRR+ vs Frequency V = 12V, V ...

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PSRR+ vs Frequency V = 22V –22V 2kΩ 200mVpp L RIPPLE 202151m9 PSRR+ vs Frequency V = 2.5V –2. 2kΩ 200mVpp L RIPPLE 202151m8 ...

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PSRR+ vs Frequency V = 12V 600Ω RIPPLE PSRR+ vs Frequency V = 22V 600Ω RIPPLE PSRR+ vs Frequency V = 2.5V ...

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PSRR+ vs Frequency V = 15V –15V 10kΩ 200mVpp L RIPPLE 202151m3 PSRR+ vs Frequency V = 12V –12V 10kΩ 200mVpp L RIPPLE 202151m1 ...

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PSRR+ vs Frequency V = 2.5V 10kΩ RIPPLE CMRR vs Frequency V = 15V 2kΩ L CMRR vs Frequency V = 22V 2kΩ ...

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CMRR vs Frequency V = 15V –15V 600Ω 202151o9 CMRR vs Frequency V = 22V –22V 600Ω 202151g5 CMRR vs Frequency V = 15V ...

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CMRR vs Frequency V = 22V 10kΩ L Output Voltage vs Load Resistance V = 15V THD Output Voltage vs Load Resistance V = 22V THD+N = ...

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Output Voltage vs Total Power Supply Voltage R = 2kΩ, THD Output Voltage vs Total Power Supply Voltage R = 10kΩ, THD Power Supply Current vs Total Power Supply Voltage = 600Ω ...

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Full Power Bandwidth vs Frequency Small-Signal Transient Response 10pF V L www.national.com Gain Phase vs Frequency 202151j0 Small-Signal Transient Response 202151i7 22 202151j1 100pF V L 202151i8 ...

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Application Information DISTORTION MEASUREMENTS The vanishingly low residual distortion produced by LME49860 is below the capabilities of all commercially avail- able equipment. This makes distortion measurements just slightly more difficult than simply connecting a distortion me- ter to the amplifier’s ...

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The LME49860 is a high speed op amp with excellent phase margin and stability. Capacitive loads up to 100pF will cause little change in the phase characteristics of the amplifiers and are therefore allowable. Capacitive loads greater than 100pF must ...

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TYPICAL APPLICATIONS NAB Preamp kHz = 0.38 μ Weighted Balanced to Single Ended Converter V = V1–V2 O 20215130 − V3 − 20215132 ...

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Second Order High Pass Filter (Butterworth) Illustration kHz 0 Illustration kHz 10 www.national.com Second Order Low Pass Filter 20215135 Illustration kHz ...

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Channel Panning Circuit (Pan Pot) 20215139 AC/DC Converter Line Driver 27 20215138 20215140 www.national.com ...

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Illustration is Hz 320 =11 kHz 1.1 kHz 0.33 μ S kHz A ...

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Illustration is 101(V2 − V1) Balanced Input Mic Amp 29 20215143 www.national.com ...

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... Note 9: At volume of change = ±12 dB    1.7    Reference: “AUDIO/RADIO HANDBOOK”, National Semiconductor, 1980, Page 2–61 www.national.com 10 Band Graphic Equalizer fo (Hz 0.12μF 4.7μF 32 75kΩ 0.056μF 3.3μF 64 68kΩ 0.033μF 1.5μF 125 62kΩ 0.015μF 0.82μ ...

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... Revision History Rev Date 1.0 06/01/07 1.1 06/11/07 Description Initial release. Added the LME49860MA and LME49860NA Top Mark Information. 31 www.national.com ...

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... Physical Dimensions www.national.com inches (millimeters) unless otherwise noted Narrow SOIC Package Order Number LME49860MA NS Package Number M08A Dual-In-Line Package Order Number LME49860NA NS Package Number N08E 32 ...

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Notes 33 www.national.com ...

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