LMH6611MK/NOPB National Semiconductor, LMH6611MK/NOPB Datasheet
LMH6611MK/NOPB
Specifications of LMH6611MK/NOPB
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LMH6611MK/NOPB Summary of contents
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... The LMH6612 is available in 8-Pin SOIC. Both the LMH6611 and LMH6612 are available in −40°C to +125°C extended indus- trial temperature grade. Typical Application WEBENCH ® registered trademark of National Semiconductor Corporation. © 2010 National Semiconductor Corporation LMH6611/LMH6612 Features specified. ■ ...
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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. ESD Tolerance (Note 2) Human Body Model For input pins only For all other pins Machine Model Charge Device Model +3V Electrical Characteristics Unless otherwise specified, all limits are guaranteed for T ≠ ...
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Symbol Parameter Input, DC Performance V Input Offset Voltage OS (LMH6611) Input Offset Voltage (LMH6612) TCV Input Offset Voltage Average Drift OS I Input Bias Current B I Input Offset Current O C Input Capacitance IN R Input Resistance IN ...
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Symbol Parameter Power Supply Performance PSRR Power Supply Rejection Ratio I Supply Current (LMH6611) S Supply Current (LMH6612) (per channel) I Disable Shutdown Current SD (LMH6611) +5V Electrical Characteristics Unless otherwise specified, all limits are guaranteed for T ≠ = ...
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Symbol Parameter Input, DC Performance V Input Offset Voltage OS (LMH6611) Input Offset Voltage (LMH6612) TCV Input Offset Voltage Average OS Drift I Input Bias Current B I Input Offset Current O C Input Capacitance IN R Input Resistance IN ...
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Symbol Parameter Power Supply Performance PSRR Power Supply Rejection Ratio I Supply Current (LMH6611) S Supply Current (LMH6612) (per channel) I Disable Shutdown Current SD (LMH6611) ±5V Electrical Characteristics Unless otherwise specified, all limits are guaranteed for T ≠ = ...
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Symbol Parameter Input DC Performance V Input Offset Voltage OS (LMH6611) Input Offset Voltage (LMH6612) TCV Input Offset Voltage Average OS Drift I Input Bias Current B I Input Offset Current O C Input Capacitance IN R Input Resistance IN ...
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Symbol Parameter Power Supply Performance PSRR Power Supply Rejection Ratio I Supply Current (LMH6611) S Supply Current (LMH6612) (per channel) I Disable Shutdown Current SD (LMH6611) Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may ...
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Typical Performance Characteristics ≠ A +1, unless otherwise specified. V Closed Loop Frequency Response for Various Supplies Closed Loop Frequency Response for Various Supplies Closed Loop Gain vs. Frequency for Various Temperatures 25° ...
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Closed Loop Gain vs. Frequency for Various Gains Large Signal Frequency Response ±0.1 dB Gain Flatness for Various Supplies www.national.com Large Signal Frequency Response 30033623 ±0.1 dB Gain Flatness for Various Supplies 30033631 ±0.1 dB Gain Flatness for Various Supplies ...
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Gain Flatness for Various Supplies Small Signal Frequency Response with Various Capacitive Load HD2 and HD3 vs. Frequency and Supply Voltage ±0.1 dB Gain Flatness for Various Supplies (Gain = +2) 30033607 Small Signal Frequency Response with Capacitive ...
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HD2 and HD3 vs. Common Mode Voltage HD2 vs. Frequency and Gain Open Loop Gain and Phase www.national.com HD2 and HD3 vs. Common Mode Voltage 30033677 HD3 vs. Frequency and Gain 30033651 HD2 vs. Output Swing 30033676 12 30033681 30033652 ...
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HD3 vs. Output Swing 30033683 HD2 vs. Output Swing 30033694 HD3 vs. Output Swing 30033685 HD2 vs. Output Swing HD3 vs. Output Swing Settling Time vs. Input Step Amplitude 13 30033693 30033684 30033686 www.national.com ...
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Settling Time vs. Input Step Amplitude www.national.com 30033687 OUT 30033661 CM 30033660 14 Input Noise vs. Frequency 30033674 V vs OUT 30033668 V vs 30033658 ...
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V vs OUT 30033669 I vs 30033659 V vs. V OUT S 30033690 15 V Distribution OS 30033672 I vs 30033657 V vs. V OUT S 30033691 www.national.com ...
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V vs. V OUT Circuit for Positive (+) PSRR Measurement Circuit for Negative (−) PSRR Measurement www.national.com Closed Loop Output Impedance vs. Frequency A S 30033671 30033688 30033689 30033696 +PSRR vs. Frequency 30033633 −PSRR vs. Frequency ...
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CMRR vs. Frequency 30033697 Small Signal Step Response 30033610 Small Signal Step Response 30033612 Crosstalk vs. Frequency Small Signal Step Response Small Signal Step Response 17 30033632 30033611 30033614 www.national.com ...
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Small Signal Step Response Small Signal Step Response Small Signal Step Response www.national.com Small Signal Step Response 30033615 Small Signal Step Response 30033617 Large Signal Step Response 30033619 18 30033616 30033618 30033613 ...
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Large Signal Step Response 30033620 I vs DISABLE 30033656 Overload Recovery Response 19 30033621 www.national.com ...
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Application Information The LMH6611 and LMH6612 are based on National Semiconductor’s proprietary VIP10 dielectrically isolated bipolar process. This device family architecture features the following: • Complimentary bipolar devices with exceptionally high f ∼ GHz) even under low supply ...
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−3 dB (MHz 665 110 1000 113 MINIMIZING NOISE With a low input voltage noise of 10 nV/ rent noise the LMH6611 and LMH6612 are suit- able for high accuracy applications. ...
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Because SINAD compares all undesired frequency compo- nents with the input frequency overall measure of an ADC’s dynamic performance. The following sections will dis- cuss the three different ADC driver architectures in detail. SINGLE TO SINGLE ADC ...
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SINGLE-ENDED TO DIFFERENTIAL ADC DRIVER The single-ended to differential ADC driver in Figure 3 utilizes an LMH6612 dual op amp to buffer a single-ended source to drive an ADC with differential inputs. One of the op amps is configured as ...
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The performance of the LMH6612 with the ADC121S625 is shown in Table 2. TABLE 2. Performance of the LMH6612 Combined with the ADC121S625 Amplifier SINAD Output/ADC Input (dB) 2.5 68.8 DIFFERENTIAL TO DIFFERENTIAL ADC DRIVER The LMH6612 dual op amp ...
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The following table summarizes the performance of the LMH6612 combined with the ADC121S625 at two different frequencies. In order to utilize the full dynamic range of the TABLE 3. Performance of the LMH6612 Combined with the ADC121S625 Amplifier SINAD Output/ADC ...
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DC LEVEL SHIFTING Often a signal must be both amplified and level shifted while using a single supply for the op amp. The circuit in can do both of these tasks. The procedure for specifying the resistor values is as ...
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CURRENT SENSE AMPLIFIER AND OPTIMIZING ACCURACY IN PRECESION APPLICATIONS With it’s rail-to-rail output capability, low V LMH6611 is an ideal choice for a current sense amplifier ap- plication. Figure 11 shows the schematic of the LMH6611 set ...
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... Many of the datasheet plots were measured with this board: Device LMH6611MK 30033635 This evaluation board can be shipped when a device sample request is placed with National Semiconductor Peaking −3 dB MEAS (MHz) (dB) 27 ...
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Physical Dimensions inches (millimeters) unless otherwise noted 6-Pin TSOT23 NS Package Number MK06A 8-Pin SOIC NS Package Number M08A 29 www.national.com ...
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