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ADC161S626EB Texas Instruments ADC161S626 Evaluation Board
ADC161S626CIMMX/NOPB Texas Instruments 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC 10-VSSOP -40 to 85
ADC161S626CIMME/NOPB Texas Instruments 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC 10-VSSOP -40 to 85
ADC161S626CIMM/NOPB Texas Instruments 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC 10-VSSOP -40 to 85
ADC161S626BEB Texas Instruments Evaluation Board for the ADC161S626BEB
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ADC161S626BEB National Semiconductor Corporation Rochester Electronics 1 $57.74 $46.91
ADC161S626BEB/NOPB Texas Instruments Rochester Electronics 1 - -
ADC161S626CIMM National Semiconductor Corporation Rochester Electronics 23 $6.44 $5.24
ADC161S626CIMM/NOPB Texas Instruments Newark element14 1,000 $5.18 $5.18
ADC161S626CIMM/NOPB Texas Instruments Texas Instruments 2,673 $8.14 $5.00
ADC161S626CIMM/NOPB Texas Instruments element14 Asia-Pacific 1 $13.26 $7.24
ADC161S626CIMM/NOPB Texas Instruments Avnet - $8.00 $6.29
ADC161S626CIMM/NOPB Texas Instruments Avnet - $5.69 $5.49
ADC161S626CIMM/NOPB National Semiconductor Corporation Rochester Electronics 564 $7.96 $6.47
ADC161S626CIMM/NOPB Texas Instruments Chip1Stop 80 $9.20 $8.13
ADC161S626CIMM/NOPB Texas Instruments Farnell element14 9 £7.99 £5.99
ADC161S626CIMM/NOPB Texas Instruments Chip1Stop 16 $9.20 $8.87
ADC161S626CIMME/NOPB Texas Instruments Texas Instruments 1,086 $8.14 $5.00
ADC161S626CIMME/NOPB National Semiconductor Corporation Rochester Electronics 45 $7.96 $6.47
ADC161S626CIMME/NOPB Texas Instruments Avnet - $6.29 $5.49
ADC161S626CIMME/NOPB Texas Instruments Farnell element14 29 £7.99 £5.99
ADC161S626CIMME/NOPB Texas Instruments element14 Asia-Pacific 19 $12.83 $7.28
ADC161S626CIMMXNOPB Texas Instruments Avnet - $8.00 $6.29
ADC161S626CIMMXNOPB Texas Instruments Avnet - $6.29 $5.49
ADC161S626EB National Semiconductor Corporation Rochester Electronics 2 $61.54 $50.00
ADC161S626EVM Texas Instruments Texas Instruments 24 $49.00 $49.00
ADC161S626EVM Texas Instruments Avnet - $50.69 $50.69

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ADC161S626 datasheet (13)

Part Manufacturer Description Type PDF
ADC161S626 National Semiconductor 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC Original PDF
ADC161S626BEB/NOPB National Semiconductor Evaluation Boards - Analog to Digital Converters (ADCs), Programmers, Development Systems, BOARD EVAL ADC FOR AFE ADC161S62 Original PDF
ADC161S626CIMM National Semiconductor 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC Original PDF
ADC161S626CIMME National Semiconductor ADC161S626 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC; Package: MINI SOIC; No of Pins: 10; Container: Reel Original PDF
ADC161S626CIMME/NOPB National Semiconductor ADC161S626 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC; Package: MINI SOIC; No of Pins: 10; Qty per Container: 250/Reel Original PDF
ADC161S626CIMME/NOPB Texas Instruments ADC161S626 - 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC 10-VSSOP -40 to 85 Original PDF
ADC161S626CIMM/NOPB National Semiconductor ADC161S626 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC; Package: MINI SOIC; No of Pins: 10; Qty per Container: 1000/Reel Original PDF
ADC161S626CIMM/NOPB Texas Instruments ADC161S626 - 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC 10-VSSOP -40 to 85 Original PDF
ADC161S626CIMMX National Semiconductor 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC Original PDF
ADC161S626CIMMX/NOPB National Semiconductor ADC161S626 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC; Package: MINI SOIC; No of Pins: 10; Qty per Container: 3500/Reel Original PDF
ADC161S626CIMMX/NOPB Texas Instruments ADC161S626 - 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC 10-VSSOP -40 to 85 Original PDF
ADC161S626EB National Semiconductor 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC Original PDF
ADC161S626EB/NOPB National Semiconductor Evaluation Boards - Analog to Digital Converters (ADCs), Programmers, Development Systems, BOARD EVAL FOR ADC161S626 Original PDF

ADC161S626 Datasheets Context Search

Catalog Datasheet MFG & Type PDF Document Tags
2008 - DGS0010A

Abstract: pin no. tda 2030
Text: of the ADC161S626. IREF changes only slightly with temperature. See the curves, "Reference Current vs , ADC161S626. The ranges of VCM are depicted in Figure 40 and Figure 41. Note that these figures only apply to , . The ADC161S626's DOUT pin is in a high impedance state when CS is high and for the first clock period , show examples of interfacing bridge sensors to the ADC161S626. The applications assume that the bridge , ADC161S626 www.ti.com SNAS468B ­ SEPTEMBER 2008 ­ REVISED MAY 2009 ADC161S626 16-Bit, 50 to 250


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PDF ADC161S626 SNAS468B ADC161S626 16-Bit, 16-bit VSSOP-10 DGS0010A pin no. tda 2030
2009 - lm402

Abstract: No abstract text available
Text: www.national.com ADC161S626 Ordering Information Order Code ADC161S626CIMM ADC161S626CIMMX ADC161S626CIMME , frequency dependent on the operating sample rate of the ADC161S626. IREF changes only slightly with , and VREF used for the ADC161S626. The ranges of VCM are depicted in Figure 10 and Figure 11. Note that , ends on the rising edge of CS. The ADC161S626's D OUT pin is in a high impedance state when CS is high , interfacing bridge sensors to the ADC161S626. The applications assume that the bridge sensors require


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PDF ADC161S626 ADC161S626 16-Bit, SNAS468B 16-bit lm402
2008 - LTSR-1513

Abstract: low noise audio amplifier tda AF124 ADC161S626
Text: of the ADC161S626. IREF changes only slightly with temperature. See the curves, "Reference Current vs , used for the ADC161S626. The ranges of VCM are depicted in Figure 40 and Figure 41. Note that these , ends on the rising edge of CS. The ADC161S626's DOUT pin is in a high impedance state when CS is high , ADC161S626 www.ti.com SNAS468C ­ SEPTEMBER 2008 ­ REVISED MARCH 2013 ADC161S626 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC Check for Samples: ADC161S626 1 FEATURES 16


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PDF ADC161S626 SNAS468C ADC161S626 16-Bit, 16-bit VSSOP-10 LTSR-1513 low noise audio amplifier tda AF124
2008 - tacq

Abstract: ADC161S626 LMP7731 MSOP-10 LM4020-2 250-KSPS 768d LM4020
Text: 16 50kSPS 250kSPS A/D ADC161S626 250kSPS 16 (SAR) A/D ADC161S626 - 40 85 ± 0.003 85dB ADC161S626 300734 20080716 ADC161S626 16 50kSPS 250kSPS ± 0.003 ADC161S626 (VA) (VIO) VA 4.5V , ADC161S626 1MHz 5MHz 2.5V 5.5V ADC161S626 10 MSOP ADC161S626 , DS300734-02-JP 1 ADC161S626 16 50kSPS 250kSPS A/D 2008 9 ADC161S626


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PDF 50kSPS 250kSPS ADC161S626 tacq ADC161S626 LMP7731 MSOP-10 LM4020-2 250-KSPS 768d LM4020
24C02N

Abstract: ADC141S626 ADC161S626 JP13
Text: ADC161S626EB /RoHS Design Kit (consisting of the ADC161S626 Evaluation Board and this User's Guide) is designed , logic analyzer, can be used with the board to evaluate the ADC161S626's performance. In the `Computer , differential signal applied across analog inputs J8.P3 and J8.P5 is digitized by U7, the ADC161S626. The , software program to analyze the ADC161S626. 4. Functional Description Table I describes the functions , signals for SCLK and CSB in order to receive an output signal DOUT from the ADC161S626. Further


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PDF ADC161S626 16-Bit, Alon737-7018 24C02N ADC141S626 JP13
2009 - X98C

Abstract: LM4120-2 LM4050 MSOP-10 ADC161S626 LM4040 ADC161S626CIMME ADC161S626CIMMX ADC161S626EB LM4120-4
Text: ADC161S626CIMMX -40°C to +85°C 10-Lead MSOP Package, 3500 Units Tape & Reel X98C ADC161S626CIMME , occur at a frequency dependent on the operating sample rate of the ADC161S626. IREF changes only , upon VA and VREF used for the ADC161S626. The ranges of VCM are depicted in Figure 10 and Figure 11 , and ends on the rising edge of CS. The ADC161S626's D OUT pin is in a high impedance state when CS , bridge sensors to the ADC161S626. The applications assume that the bridge sensors require buffering and


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PDF ADC161S626 16-Bit, ADC161S626 16-bit X98C LM4120-2 LM4050 MSOP-10 LM4040 ADC161S626CIMME ADC161S626CIMMX ADC161S626EB LM4120-4
2008 - af124

Abstract: No abstract text available
Text: operating sample rate of the ADC161S626. IREF changes only slightly with temperature. See the curves , and VREF used for the ADC161S626. The ranges of VCM are depicted in Figure 40 and Figure 41. Note , the falling edge of CS and ends on the rising edge of CS. The ADC161S626's DOUT pin is in a high , ADC161S626 www.ti.com SNAS468C – SEPTEMBER 2008 – REVISED MARCH 2013 ADC161S626 16-Bit, 50 to 250 kSPS, Differential Input, MicroPower ADC Check for Samples: ADC161S626 FEATURES KEY


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PDF ADC161S626 SNAS468C ADC161S626 16-Bit, 16-bit af124
2008 - vcm sensor

Abstract: ADC161S626 LMP7731 MSOP-10 LM4020-2 LM402 tda 1111 lm4020
Text: 16 50kSPS 250kSPS A/D ADC161S626 250kSPS 16 (SAR) A/D ADC161S626 - 40 85 ± 0.003 85dB ADC161S626 300734 20080716 ADC161S626 16 50kSPS 250kSPS ± 0.003 ADC161S626 (VA) (VIO) VA 4.5V , ADC161S626 1MHz 5MHz 2.5V 5.5V ADC161S626 10 MSOP ADC161S626 , DS300734-02-JP 1 ADC161S626 16 50kSPS 250kSPS A/D 2008 9 ADC161S626


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PDF 50kSPS 250kSPS ADC161S626 vcm sensor ADC161S626 LMP7731 MSOP-10 LM4020-2 LM402 tda 1111 lm4020
2008 - TDA audio power amplifier

Abstract: TDA audio power amplifier 1.2 volt TDA audio amplifier circuits ADC161S626 tda audio amplifier ADC161S626CIMM MSOP-10 single phase to three phase conversion in 3 phase sensor interface LM4120
Text: ADC161S626CIMMX -40°C to +85°C 10-Lead MSOP Package, 3500 Units Tape & Reel X98C ADC161S626EB , occur at a frequency dependent on the operating sample rate of the ADC161S626. IREF changes only , used for the ADC161S626. The ranges of VCM are depicted in Figure 10 and Figure 11. Note that these , and ends on the rising edge of CS. The ADC161S626's D OUT pin is in a high impedance state when CS , show examples of interfacing bridge sensors to the ADC161S626. The applications assume that the


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PDF ADC161S626 16-Bit, ADC161S626 16-bit TDA audio power amplifier TDA audio power amplifier 1.2 volt TDA audio amplifier circuits tda audio amplifier ADC161S626CIMM MSOP-10 single phase to three phase conversion in 3 phase sensor interface LM4120
2012 - Not Available

Abstract: No abstract text available
Text: The ADC161S626EB /RoHS Design Kit (consisting of the ADC161S626 Evaluation Board and this User's Guide , equipments, such as a logic analyzer, can be used with the board to evaluate the ADC161S626†™s performance , U7, the ADC161S626. The ADC161S626 uses an oscillator that is provided on this board by Y2 or is , WaveVision software program to analyze the ADC161S626. 4. Functional Description Table I describes the , the ADC161S626. Further descriptions of those pins are discussed below. 4.3.1 Serial Clock


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PDF ADC161S626 16-Bit,
LMP2021

Abstract: ADC121S101 ADC161S626 LMP7731
Text: / : ­ ­ ­ ­ ­ / /? ­ ­ / (CMRR) (PSRR) - / (LSB) / ( ADC161S626 1/2 (LSB) LMP2021 (VOS) 5uV 18 / ½ (LSB) / 14 16 18 ½ , =(1+2R5/R7)(R1/R2) ADC161S626 2 Single Pole Gain Function -20 System Resolution 8 bit 9 , kSPS ADC161S626 0.8% 99.2% (5.8 × 0.8%) + (0.01 × 99.2%) = 0.056 mW = 56W. -


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PDF ADC161S626 LMP2021 -40oC 125oC LMP2021 ADC121S101 ADC161S626 LMP7731
2015 - SIGNAL PATH designer

Abstract: LMP8358 ADC161S626 asic ic DAC122S085 LMP7702
Text: DAC122S085 VOUT A +5 VA +5 VA VREF DOUT -.23 VA ADC161S626 CS MCU , DC 0V A/D 16 ADC161S626 DC -0.23V / LM7705


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rtd temperature sensor amplifier

Abstract: LMP2021 weight sensor interface WITH ADC ADC121S101 ADC161S626 LMP7731
Text: 's maximum offset (1/2 LSB for the ADC161S626 ), or it should be trimmed through hardware or software. ADC , +V 3 R1 10K 1 R4 10K R3 10K Av=(1+2R5/R7)(R1/R2) 19 ADC161S626 2 Closed , . Average power consumption= Active Power x % active) + (PD Power x % PD) Example ADC161S626 @ 5V power


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PDF ADC161S626 rtd temperature sensor amplifier LMP2021 weight sensor interface WITH ADC ADC121S101 ADC161S626 LMP7731
2008 - AF5A

Abstract: LMP2021MFE LMP2021MF LMP2022MA LMP2021MA LMP2022MMX LMP2022 av5a LMP2021 LMP2021MFX
Text: LMP2022 and one LMP2021 in front of the ADC161S626. The gaining of this 20 mV signal is achieved in 2 , ADC161S626. The ADC161S626 is a 16-bit, 50 kSPS to 250 kSPS 5V ADC. In order to utilize the maximum number of bits of the ADC161S626 in this configuration, a 2.5V reference voltage is used. This 2.5V reference is , and equal to the reference voltage of the ADC161S626 , 2.5V. This excitation voltage results in 2.5V , /LMP2022 used with ADC161S626 17 www.national.com LMP2021/LMP2022 Physical Dimensions inches


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PDF LMP2021/LMP2022 AF5A LMP2021MFE LMP2021MF LMP2022MA LMP2021MA LMP2022MMX LMP2022 av5a LMP2021 LMP2021MFX
2009 - AF5A

Abstract: instrumentation amplifier low pass filter weigh av5a LMV77 LMP2021MFX LMP2021MFE LMP2021MF LMP2021MA LMP2021 LMP2022MA
Text: LMP2022 and one LMP2021 in front of the ADC161S626. The gaining of this 20 mV signal is achieved in 2 , the ADC161S626. The ADC161S626 is a 16-bit, 50 kSPS to 250 kSPS 5V ADC. In order to utilize the maximum number of bits of the ADC161S626 in this configuration, a 2.5V reference voltage is used. This , voltage and equal to the reference voltage of the ADC161S626 , 2.5V. This excitation voltage results in , FIGURE 12. LMP2021/LMP2022 used with ADC161S626 17 www.national.com LMP2021/LMP2022 Physical


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PDF LMP2021/LMP2022 LMP2021/LMP2022 AF5A instrumentation amplifier low pass filter weigh av5a LMV77 LMP2021MFX LMP2021MFE LMP2021MF LMP2021MA LMP2021 LMP2022MA
2010 - lidar

Abstract: LIDAR radar ADC16DV160 LMP7312 LMP8358 motion sensor interface WITH ADC weight sensor interface WITH ADC LM26480 DAC128S085 DAC124S085
Text: , ADC124Sxxx, ADC128Sxxx*, ADC161S626 Amplifier LMP2021/22*, LMP7312, LMP8358 Analog Power ! , , ADC128Sxxx*, ADC161S626 Amplifier LMP2021/22*, LMP7312, LMP8358, LMP8601Q/2Q/3Q Analog Power


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PDF functionalit52 lidar LIDAR radar ADC16DV160 LMP7312 LMP8358 motion sensor interface WITH ADC weight sensor interface WITH ADC LM26480 DAC128S085 DAC124S085
2008 - av5a

Abstract: LMP2021 AF5A LMP2021MF LMP2022MA LMP2021MA LMP2022MMX LMP2022 LMP20 LMP2021MFX
Text: LMP2022 and one LMP2021 in front of the ADC161S626. The gaining of this 20 mV signal is achieved in 2 , ADC161S626. The ADC161S626 is a 16-bit, 50 kSPS to 250 kSPS 5V ADC. In order to utilize the maximum number of bits of the ADC161S626 in this configuration, a 2.5V reference voltage is used. This 2.5V reference is , ADC161S626 + 0.1 PF 5.1 k: 0.1% - 1/2 LMP2022 VR = 1/2 VA 200: 1 k: + The LMP2021/LMP2022 , and equal to the reference voltage of the ADC161S626 , 2.5V. This excitation voltage results in 2.5V


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PDF LMP2021, LMP2022 LMP2021/LMP2022 av5a LMP2021 AF5A LMP2021MF LMP2022MA LMP2021MA LMP2022MMX LMP2022 LMP20 LMP2021MFX
2008 - Not Available

Abstract: No abstract text available
Text: is done by using one LMP2022 and one LMP2021 in front of the ADC161S626. The gaining of this 20 mV , amplified signal is then fed into the ADC161S626. The ADC161S626 is a 16-bit, 50 kSPS to 250 kSPS 5V ADC. In order to utilize the maximum number of bits of the ADC161S626 in this configuration, a 2.5V , LMP2021 280: R3 ADC161S626 - + VA - 0.1 PF 5.1 k: 0.1% 1/2 LMP2022 + VR , analog supply voltage and equal to the reference voltage of the ADC161S626 , 2.5V. This excitation


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PDF LMP2021, LMP2022 LMP2021/LMP2022
2009 - LMV7

Abstract: av5a AF5A LMP2021MFX LMP2022MA LMP2021MA LMP2022MMX LMP2022 LMP2021 LMP20
Text: LMP2022 and one LMP2021 in front of the ADC161S626. The gaining of this 20 mV signal is achieved in 2 , ADC161S626. The ADC161S626 is a 16-bit, 50 kSPS to 250 kSPS 5V ADC. In order to utilize the maximum number of bits of the ADC161S626 in this configuration, a 2.5V reference voltage is used. This 2.5V reference is , and equal to the reference voltage of the ADC161S626 , 2.5V. This excitation voltage results in 2.5V , /LMP2022 used with ADC161S626 17 www.national.com LMP2021/LMP2022 Physical Dimensions inches


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PDF LMP2021 LMP2022 LMP2021/LMP2022 LMV7 av5a AF5A LMP2021MFX LMP2022MA LMP2021MA LMP2022MMX LMP2022 LMP20
2010 - schematic diagram brushless motor control

Abstract: sensor motor DC schematic diagram Brushed TO Brushless Converter circuit diagram how to interface microcontroller with encoder DC MOTOR SPEED CONTROLLER in fpga speed control of dc motor by using DAC LMP8358 LMP7702 PROGRAMMABLE PRESSURE TRANSDUCER CIRCUIT how to interface pulse sensor with microcontroller
Text: , helping maintain an accurate zero and a full scale for the 16-bit ADC, ADC161S626. In this circuit, a , -.23 VA ADC161S626 Bridge Transducer CS MCU FPGA SCLK In Amp Transducer Offset


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types of sensor

Abstract: lm35 to 4-20ma LM35 application circuits op-amp with 4-20ma ADC INPUT 4-20ma interface WITH ADC LMV521 4-20ma to digital ADC lm7332 4-20ma spi Data Acquisition
Text: ) · ADC161S626 (alone for 5V inputs or with Op Amp) · LMP7716 (up to 5V) · LMP7702 (high voltage


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PDF LMP7717) LMP7715, LMV641) LM8261) LMP7731) LMV521) LMP2021) types of sensor lm35 to 4-20ma LM35 application circuits op-amp with 4-20ma ADC INPUT 4-20ma interface WITH ADC LMV521 4-20ma to digital ADC lm7332 4-20ma spi Data Acquisition
2008 - bs270 spice

Abstract: BS270 SIGNAL PATH designer ADC121S101 ADC161S626 LMV762 novasensornpc-1210npc-1210 7NPC-1210
Text: ) VSENSOR_OUT = y x () x A/DADC121S101 SP1602S02RB 2 16 V SENSOR_OUT A/D ADC161S626


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PDF NovaSensorNPC-1210NPC-1210 FSO10 50mV10 ADC121S101 SP1202S01RB NPC-1210 550263-019-JP bs270 spice BS270 SIGNAL PATH designer ADC121S101 ADC161S626 LMV762 novasensornpc-1210npc-1210 7NPC-1210
ADC161S626

Abstract: LMP7731 MSOP-10 Signal Path Designer
Text: capabilities ADC161S626 16-Bit, 250 kSPS, Differential Input Micro-Power A/D Converter LMP7731 2.9 nV Hz


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2010 - Not Available

Abstract: No abstract text available
Text: of the ADC161S626 the VREF of the ADC should be set to half of the input or 1V. This is done by the resistor divider on the VREF pin of the ADC161S626. The negative input of the ADC and the REFF and REFS , example is the same as the LMP8358 and ADC161S626 supply voltage of +5V. This 10mV signal must be , ground. The resistor and capacitor between the LMP8358 and the ADC161S626 serve a dual purpose. The , the LMP8358 from the capacitive load. The values listed in the ADC161S626 datasheet are 180 for the


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PDF LMP8358 LMP8358 SNOSB09A
2010 - Thermopile amplifier

Abstract: LMP8358 Solid state thermopile sensor A115 C101 JESD22 M14A ADC161S626 LMP8358MA
Text: from the LMP8358 of 2V. To use the complete range of the ADC161S626 the VREF of the ADC should be set to half of the input or 1V. This is done by the resistor divider on the VREF pin of the ADC161S626. , 5V = 10mV. The bridge voltage in this example is the same as the LMP8358 and ADC161S626 supply , the LMP8358 and the ADC161S626 serve a dual purpose. The capacitor is a charge reservoir for the , . The values listed in the ADC161S626 datasheet are 180 for the resistor and the 470pF for the


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PDF LMP8358 LMP8358 Thermopile amplifier Solid state thermopile sensor A115 C101 JESD22 M14A ADC161S626 LMP8358MA
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