DIE Analog-to-Digital Converters 186

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Part	Manufacturer	Converter Type	Temperature Grade	Terminal Form	No. of Terminals	Package Code	Package Shape	Total Dose (V)	No. of Analog In Channels	Surface Mount	Maximum Analog Input Voltage	Sample Rate	No. of Functions	Technology	Screening Level	No. of Bits	Maximum Supply Current	Maximum Linearity Error (EL)	Nominal Supply Voltage	Output Bit Code	Power Supplies (V)	Nominal Negative Supply Voltage	Package Style (Meter)	Package Equivalence Code	Sub-Category	Minimum Supply Voltage	Maximum Operating Temperature	Minimum Analog Input Voltage	Output Format	Minimum Operating Temperature	Terminal Finish	Sample and Hold/Track and Hold	Terminal Position	Maximum Conversion Time	JESD-30 Code	Moisture Sensitivity Level (MSL)	Maximum Seated Height	Width	Qualification	Additional Features	JESD-609 Code	Maximum Time At Peak Reflow Temperature (s)	Peak Reflow Temperature (C)	Length
ADS1278SKGDA	Texas Instruments	Analog To Digital Converter, Delta-Sigma	Military	No Lead	96	DIE	Rectangular		8	Yes	5.25 V	144 kHz	1			24	185 mA	0.0014 %	5 V	2's Complement Binary	1.8/3.3,5 V		Uncased Chip	DIE OR CHIP	Analog to Digital Converters	1.65 V	210 °C (410 °F)	-2.5 V	Parallel, 8 Bits	-55 °C (-67 °F)			Upper		R-XUUC-N96				No
ICL7117C/D	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Commercial	No Lead	40	DIE	Rectangular		1	Yes	2 V		1	CMOS		16		0.0015 %	9 V	Binary	±5 V	-5 V	Uncased Chip	DIE OR CHIP	Analog to Digital Converters		70 °C (158 °F)		Parallel, Word	0 °C (32 °F)	Tin Lead		Upper		R-XUUC-N40				No		e0
ADS6142SKGD1	Texas Instruments	Analog To Digital Converter, Proprietary Method	Other	No Lead		DIE	Square		1	Yes	2 V	65 MHz	1	CMOS		14		0.061 %	3 V	Offset Binary, 2's Complement Binary			Uncased Chip				210 °C (410 °F)	-2 V	Parallel, Word	-40 °C (-40 °F)		Sample	Upper	15 ns	S-XUUC-N					Peak-to-peak input voltage range: 2 V
ADC0848MDC	Texas Instruments	Analog To Digital Converter, Successive Approximation	Commercial	No Lead		DIE			8	Yes	5.05 V		1	CMOS		8			5 V	Binary			Uncased Chip				70 °C (158 °F)	-50 mV	Parallel, 8 Bits	0 °C (32 °F)			Upper	60 µs	X-XUUC-N				No
ADC081S101MWC	Texas Instruments	Analog To Digital Converter, Successive Approximation	Industrial	No Lead		DIE			1	Yes	5.25 V	1 MHz	1	CMOS		8	3.2 mA	0.1172 %		Binary			Uncased Chip				85 °C (185 °F)	0 mV	Serial	-40 °C (-40 °F)		Track	Upper		X-XUUC-N	1
ADS8320SKGD2	Texas Instruments	Analog To Digital Converter, Successive Approximation	Military	No Lead	8	DIE	Rectangular		1	Yes	5.25 V	100 kHz	1	CMOS		16		0.034 %	2.7 V	Binary			Uncased Chip			2.7 V	210 °C (410 °F)	0 mV	Serial	-55 °C (-67 °F)		Sample	Upper	6.66667 µs	R-XUUC-N8			0.057 in (1.4503 mm)						0.072 in (1.8204 mm)
5962R0722701V9A	Texas Instruments	Analog To Digital Converter, Successive Approximation	Military	No Lead		DIE		100k Rad(Si)	8	Yes	5.25 V	1 MHz	1	CMOS	MIL-PRF-38535 Class V	12		0.0122 %	3 V	Binary			Uncased Chip			2.7 V	125 °C (257 °F)	0 mV	Serial	-55 °C (-67 °F)		Track	Upper	812.5 ns	X-XUUC-N	1			Yes
ADS1243SKGD1	Texas Instruments	Analog To Digital Converter, Delta-Sigma	Military	No Lead		DIE	Rectangular		8	Yes	5.25 V	15 Hz	1			24		0.0025 %	3 V	Binary			Uncased Chip			2.7 V	210 °C (410 °F)	0 mV	Serial	-55 °C (-67 °F)		Sample	Upper		R-XUUC-N
ADS8320SKGD1	Texas Instruments	Analog To Digital Converter, Successive Approximation	Military	No Lead	8	DIE	Rectangular		1	Yes	5.25 V	100 kHz	1	CMOS		16		0.034 %	2.7 V	Binary			Uncased Chip			2.7 V	210 °C (410 °F)	0 mV	Serial	-55 °C (-67 °F)		Sample	Upper	6.666 µs	R-XUUC-N8			0.06 in (1.5263 mm)	No					0.075 in (1.8964 mm)
ADC08831MDC	Texas Instruments	Analog To Digital Converter, Successive Approximation	Industrial	No Lead		DIE			1	Yes	5.05 V	181 kHz	1	CMOS		8			5 V	Binary			Uncased Chip				85 °C (185 °F)	-50 mV	Serial	-40 °C (-40 °F)		Track	Upper	4 µs	X-XUUC-N				No
ADC0848MWC	Texas Instruments	Analog To Digital Converter, Successive Approximation	Commercial	No Lead		DIE			8	Yes	5.05 V		1	CMOS		8			5 V	Binary			Uncased Chip				70 °C (158 °F)	-50 mV	Parallel, 8 Bits	0 °C (32 °F)			Upper	60 µs	X-XUUC-N				No
ADS1282SKGDA	Texas Instruments	Analog To Digital Converter, Delta-Sigma	Military	No Lead	30	DIE	Rectangular		2	Yes	1.25 V	4 kHz	1			24	10 mA	0.009 %	2.5 V	2's Complement Binary		-2.5 V	Uncased Chip				210 °C (410 °F)	-1.25 V	Serial	-55 °C (-67 °F)			Upper		R-XUUC-N30				No
ADC128S102MDR	Texas Instruments	Analog To Digital Converter, Successive Approximation	Military	No Lead		DIE			8	Yes	5.25 V	1 MHz	1	CMOS		12		0.0342 %	3 V	Binary			Uncased Chip			2.7 V	125 °C (257 °F)	0 mV	Serial	-55 °C (-67 °F)		Track	Upper	16.25 µs	X-XUUC-N	1
ADC08832MWC	Texas Instruments	Analog To Digital Converter, Successive Approximation	Industrial	No Lead		DIE			2	Yes	5.05 V	153 kHz	1	CMOS		8			5 V	Binary			Uncased Chip				85 °C (185 °F)	-50 mV	Serial	-40 °C (-40 °F)		Track	Upper	4 µs	X-XUUC-N				No
5962R0722701V9X	Texas Instruments	Analog To Digital Converter, Successive Approximation	Military	No Lead	16	DIE	Rectangular	100k Rad(Si)	8	Yes	5.25 V	1 MHz	1	CMOS	MIL-PRF-38535 Class V	12	3.1 mA	0.0342 %	3 V	Binary			Uncased Chip				125 °C (257 °F)	0 mV	Serial	-55 °C (-67 °F)		Track	Upper	16.25 µs	R-XUUC-N16				Yes
ADC08832MDC	Texas Instruments	Analog To Digital Converter, Successive Approximation	Industrial	No Lead		DIE			2	Yes	5.05 V	153 kHz	1	CMOS		8			5 V	Binary			Uncased Chip				85 °C (185 °F)	-50 mV	Serial	-40 °C (-40 °F)		Track	Upper	4 µs	X-XUUC-N				No
ADC08831MWC	Texas Instruments	Analog To Digital Converter, Successive Approximation	Industrial	No Lead		DIE			1	Yes	5.05 V	181 kHz	1	CMOS		8			5 V	Binary			Uncased Chip				85 °C (185 °F)	-50 mV	Serial	-40 °C (-40 °F)		Track	Upper	4 µs	X-XUUC-N				No
AD670-000C	Analog Devices	Analog To Digital Converter, Proprietary Method	Military	No Lead	20	DIE	Rectangular		1	Yes			1			8			5 V	Binary			Uncased Chip				125 °C (257 °F)		Parallel, 8 Bits	-55 °C (-67 °F)			Upper	10 µs	R-XUUC-N20
AD7714ACHIPS-3	Analog Devices	Analog To Digital Converter, Delta-Sigma	Industrial	No Lead	24	DIE	Rectangular		5	Yes	2.5 V		1	CMOS		24		0.0015 %	3 V	Binary, Offset Binary			Uncased Chip				85 °C (185 °F)	-2.5 V	Serial	-40 °C (-40 °F)			Upper		R-XUUC-N	3			No			30 s	260 °C (500 °F)
AD7821BCHIPS	Analog Devices	Analog To Digital Converter, Flash Method	Industrial	No Lead	20	DIE			1	Yes	2.5 V	1 MHz	1	BICMOS		8		0.3906 %	5 V	Binary, Offset Binary		-5 V	Uncased Chip				85 °C (185 °F)	-2.5 V	Parallel, 8 Bits	-40 °C (-40 °F)		Track	Upper	660 ns	X-XUUC-N20				No
AD7713ACHIPS	Analog Devices	Analog To Digital Converter, Delta-Sigma	Industrial	No Lead		DIE			3	Yes	10 V	3.9 kHz	1	CMOS		24		0.0015 %	5 V	Binary, Offset Binary			Uncased Chip				85 °C (185 °F)	0 mV	Serial	-40 °C (-40 °F)	Matte Tin	Sample	Upper		X-XUUC-N	1			No		e3
AD570SCHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation	Military	No Lead	18	DIE	Rectangular		1	Yes	5 V		1	Bipolar		8		0.2 %	5 V	Binary, Offset Binary	5,-12/-15 V	-15 V	Uncased Chip	DIE OR CHIP	Analog to Digital Converters		125 °C (257 °F)	-5 V	Parallel, 8 Bits	-55 °C (-67 °F)			Upper	40 µs	R-XUUC-N18				No
AD7823YCHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation		No Lead	8	DIE			1	Yes	5.5 V		1			8		0.3906 %	3 V	Binary			Uncased Chip					0 mV	Serial			Track	Upper	4 µs	X-XUUC-N8				No
AD7895ACHIPS-10	Analog Devices	Analog To Digital Converter, Successive Approximation		No Lead		DIE			1	Yes	10 V		1			12		0.0244 %	5 V	2's Complement Binary			Uncased Chip					-10 V	Serial			Track	Upper	3.8 µs	X-XUUC-N				No
AD7824BCHIPS	Analog Devices	Analog To Digital Converter, Flash Method	Industrial	No Lead	24	DIE			4	Yes	5 V		1	CMOS		8		0.3906 %	5 V	Binary, Complementary Offset Binary	5 V		Uncased Chip	DIE OR CHIP	Analog to Digital Converters		85 °C (185 °F)	0 mV	Parallel, 8 Bits	-40 °C (-40 °F)		Track	Upper	2.5 µs	X-XUUC-N24				No
AD7574ACHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation	Other	No Lead	18	DIE			1	Yes	15 V		1	CMOS		8		0.293 %	5 V	Binary, Offset Binary, Complementary Offset Binary	5 V		Uncased Chip	DIE OR CHIP	Analog to Digital Converters		85 °C (185 °F)	-15 V	Parallel, 8 Bits	-25 °C (-13 °F)			Upper	15 µs	X-XUUC-N18				No
AD7576SCHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation	Commercial	No Lead	18	DIE			1	Yes	2.46 V		1	CMOS		8			5 V	Binary			Uncased Chip				70 °C (158 °F)	0 mV	Parallel, 8 Bits	0 °C (32 °F)	Tin Lead		Upper	20 µs	X-XUUC-N18				No		e0
AD7981-KGD-WP	Analog Devices	Analog To Digital Converter, Successive Approximation	Military	No Lead	14	DIE	Rectangular		1	Yes	5.1 V	600 kHz	1			16		0.0031 %	2.5 V	Binary			Uncased Chip				175 °C (347 °F)	0 mV	Serial	-55 °C (-67 °F)			Upper	1.377 µs	R-XUUC-N14		0.03 in (0.75 mm)	0.06 in (1.52 mm)						0.09 in (2.285 mm)
AD7874ACHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation	Industrial	No Lead		DIE			4	Yes	10 V	29 MHz	1	CMOS		12			5 V	2's Complement Binary		-5 V	Uncased Chip				85 °C (185 °F)	-10 V	Parallel, Word	-40 °C (-40 °F)		Track	Upper	35 µs	X-XUUC-N	3			No			30 s	240 °C (464 °F)
AD9027CHIPS	Analog Devices	Analog To Digital Converter, Flash Method		No Lead	28	DIE	Rectangular		1	Yes		31 MHz	1	Bipolar		12	258 mA		5 V	Offset Binary		-5.2 V	Uncased Chip						Parallel, Word		Tin Lead	Track	Upper		R-XUUC-N28				No		e0
AD7891ACHIPS-2	Analog Devices	Analog To Digital Converter, Proprietary Method		No Lead		DIE			8	Yes	2.5 V	500 kHz	1			12		0.0244 %	5 V	Binary, 2's Complement Binary			Uncased Chip					-2.5 V	Serial, Parallel, Word			Track	Upper	1.6 µs	X-XUUC-N				No
AD7714ACHIPS-5	Analog Devices	Analog To Digital Converter, Delta-Sigma	Industrial	No Lead	24	DIE	Rectangular		5	Yes	2.5 V		1	CMOS		24		0.0015 %	5 V	Binary, Offset Binary			Uncased Chip				85 °C (185 °F)	-2.5 V	Serial	-40 °C (-40 °F)			Upper		R-XUUC-N	3			No			30 s	260 °C (500 °F)
ADC922G	Analog Devices	Analog To Digital Converter Subsystem		No Lead	28	DIE	Rectangular		1	Yes	25 V	500 kHz	1					0.024 %	15 V	Binary		-15 V	Uncased Chip					-25 V	Parallel, Word		Tin Lead		Upper		R-XUUC-N28				No		e0
AD976AACHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation	Industrial	No Lead		DIE			1	Yes	10 V	200 kHz	1	BICMOS		16		0.0046 %	5 V	2's Complement Binary			Uncased Chip				85 °C (185 °F)	-10 V	Parallel, Word	-40 °C (-40 °F)	Tin Lead	Sample	Upper	4 µs	X-XUUC-N	3			No		e0		240 °C (464 °F)
AD7417ACHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation		No Lead		DIE			4	Yes	2.625 V		1			10		0.0977 %	3 V	2's Complement Binary			Uncased Chip					0 mV	Serial		Tin Lead	Track	Upper	15 µs	X-XUUC-N				No		e0
AD9058CHIPS	Analog Devices	Analog To Digital Converter, Proprietary Method		No Lead	42	DIE	Rectangular		1	Yes	1 V	50 MHz	2			8			5 V	Binary		-5 V	Uncased Chip					-1 V	Parallel, 8 Bits		Tin Lead		Upper		R-XUUC-N42				No		e0
AD7820BCHIPS	Analog Devices	Analog To Digital Converter, Flash Method	Industrial	No Lead	20	DIE			1	Yes	5 V		1	CMOS		8		0.3906 %	5 V	Binary	5 V		Uncased Chip	DIE OR CHIP	Analog to Digital Converters		85 °C (185 °F)	0 mV	Parallel, 8 Bits	-40 °C (-40 °F)		Track	Upper	1.36 µs	X-XUUC-N20				No
AD7712ACHIPS	Analog Devices	Analog To Digital Converter, Delta-Sigma	Industrial	No Lead		DIE			2	Yes	10 V		1	CMOS		24		0.003 %	5 V	Binary, Offset Binary		-5 V	Uncased Chip				85 °C (185 °F)	-10 V	Serial	-40 °C (-40 °F)	Matte Tin	Sample	Upper		X-XUUC-N	1			No		e3
AD574R000C	Analog Devices	Analog To Digital Converter, Proprietary Method	Military	No Lead	28	DIE	Rectangular		1	Yes	15 V		1	Bipolar	MIL-PRF-38534	12		0.012 %	12 V	Binary	5,±12/±15 V	-12 V	Uncased Chip	DIE OR CHIP	Analog to Digital Converters		125 °C (257 °F)	-15 V	Parallel, Word	-55 °C (-67 °F)			Upper	35 µs	R-XUUC-N28				No
AD7730BCHIPS	Analog Devices	Analog To Digital Converter, Delta-Sigma	Industrial	No Lead	24	DIE	Rectangular		2	Yes	800 mV		1			19			5 V	Binary			Uncased Chip				85 °C (185 °F)	-800 mV	Serial	-40 °C (-40 °F)			Upper		R-XUUC-N24				No
AD7715ACHIPS-5	Analog Devices	Analog To Digital Converter, Delta-Sigma	Industrial	No Lead	16	DIE	Rectangular		1	Yes	2.5 V		1	CMOS		16		0.0015 %	5 V	Binary, Offset Binary			Uncased Chip				85 °C (185 °F)	-2.5 V	Serial	-40 °C (-40 °F)			Upper		R-XUUC-N16				No
AD7574SCHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation	Commercial	No Lead	18	DIE			1	Yes	15 V		1	CMOS		8		0.293 %	5 V	Binary, Offset Binary, Complementary Offset Binary			Uncased Chip				70 °C (158 °F)	-15 V	Parallel, 8 Bits	0 °C (32 °F)			Upper	15 µs	X-XUUC-N18				No
PM7574G	Analog Devices	Analog To Digital Converter, Successive Approximation		No Lead	18	DIE	Rectangular		1	Yes	20 V		1	CMOS		8		0.293 %	5 V	Binary, Offset Binary			Uncased Chip					-20 V	Parallel, 8 Bits		Tin Lead		Upper	17 µs	R-XUUC-N18				No		e0
AD7893ACHIPS-5	Analog Devices	Analog To Digital Converter, Successive Approximation	Industrial	No Lead		DIE			1	Yes	5 V		1	BICMOS		12			5 V	Binary			Uncased Chip				85 °C (185 °F)	0 mV	Serial	-40 °C (-40 °F)		Track	Upper	6 µs	X-XUUC-N				No			30 s	220 °C (428 °F)
AD571SCHIPS	Analog Devices	Analog To Digital Converter, Successive Approximation	Military	No Lead	18	DIE			1	Yes	5 V		1	Bipolar		10		0.098 %	5 V	Binary, Offset Binary	5,-12/-15 V	-15 V	Uncased Chip	DIE OR CHIP	Analog to Digital Converters		125 °C (257 °F)	-5 V	Parallel, Word	-55 °C (-67 °F)			Upper	40 µs	X-XUUC-N18				No
AD574-000C	Analog Devices	Analog To Digital Converter, Proprietary Method	Military	No Lead	28	DIE	Rectangular		1	Yes	15 V		1	Bipolar	MIL-PRF-38534	12		0.012 %	12 V	Binary	5,±12/±15 V	-12 V	Uncased Chip	DIE OR CHIP	Analog to Digital Converters		125 °C (257 °F)	-15 V	Parallel, Word	-55 °C (-67 °F)			Upper	35 µs	R-XUUC-N28				No
AD7715ACHIPS-3	Analog Devices	Analog To Digital Converter, Delta-Sigma	Industrial	No Lead	16	DIE	Rectangular		1	Yes	1.25 V		1	CMOS		16		0.0015 %	3 V	Binary, Offset Binary			Uncased Chip				85 °C (185 °F)	-1.25 V	Serial	-40 °C (-40 °F)			Upper		R-XUUC-N				No
ADC912AGBC	Analog Devices	Analog To Digital Converter, Successive Approximation	Other	No Lead	24	DIE	Rectangular		1	Yes	15 V		1	CMOS		12	7 mA	0.024 %	5 V	Offset Binary	5,-12/-15 V		Uncased Chip	DIE OR CHIP	Analog to Digital Converters		25 °C (77 °F)	-15 V	Parallel, Word	25 °C (77 °F)	Tin Lead		Upper	11.2 µs	R-XUUC-N24				No		e0

Analog-to-Digital Converters

Analog-to-digital converters (ADCs) are electronic devices that convert continuous analog signals into digital signals, which can be processed by digital circuits, microcontrollers, or computers. ADCs are essential components in many electronic systems, as they allow the measurement and processing of physical signals, such as temperature, pressure, light, and sound.

ADCs work by sampling the analog signal at regular intervals and quantizing the sampled signal into a series of digital values. The sampling rate and the resolution of the ADC determine the accuracy and the bandwidth of the digital signal. ADCs may also include features such as amplification, filtering, or signal conditioning, to improve the accuracy and stability of the digital signal.

ADCs can be classified based on their architecture and their application. The most common types of ADCs are successive approximation ADCs, delta-sigma ADCs, and pipeline ADCs. Each type has its advantages and limitations, depending on the application and the required performance.

ADCs are used in a wide range of applications, from consumer electronics, such as smartphones and digital cameras, to industrial automation, medical devices, and scientific instruments. They play a crucial role in the conversion of physical signals into digital signals, allowing the processing, storage, and transmission of data in electronic systems.

Overall, ADCs are essential components in many electronic systems, providing the necessary signal conversion for a wide range of applications. Their accuracy, speed, and resolution determine the performance and the functionality of many electronic devices and systems.