J Bend Analog-to-Digital Converters 742

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Part	Manufacturer	Converter Type	Temperature Grade	Terminal Form	No. of Terminals	Package Code	Package Shape	Package Body Material	No. of Analog In Channels	Surface Mount	Maximum Analog Input Voltage	Sample Rate	No. of Functions	Technology	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	Terminal Pitch	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	JESD-609 Code	Maximum Time At Peak Reflow Temperature (s)	Peak Reflow Temperature (C)	Length
MAX1125BIBH	Maxim Integrated	Analog To Digital Converter, Flash Method	Other	J Bend	44	QCCJ	Square	Ceramic, Metal-Sealed Cofired	1	Yes	0 mV	300 MHz	1	CMOS	8	550 mA	0.3711 %		Binary, 2's Complement Binary		-5.2 V	Chip Carrier				85 °C (185 °F)	-2 V	Parallel, 8 Bits	-20 °C (-4 °F)	Tin Lead	Track	Quad		S-CQCC-J44				No	e0
MAX138CQH	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Commercial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	200 mV		1	CMOS	24		0.0015 %	5 V	Binary	5 V		Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	70 °C (158 °F)		Parallel, Word	0 °C (32 °F)	Tin Lead		Quad		S-PQCC-J44	3	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e0			0.653 in (16.585 mm)
MAX138EQH	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Industrial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	200 mV		1	CMOS	24		0.0015 %	5 V	Binary	5 V		Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	85 °C (185 °F)		Parallel, Word	-40 °C (-40 °F)	Tin Lead		Quad		S-PQCC-J44	3	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e0			0.653 in (16.585 mm)
MAX134EQH+TD	Maxim Integrated	Analog To Digital Converter, Proprietary Method	Industrial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	3.3 V		1	Bipolar	4		1 %	5 V	9's Complement Binary Coded Decimal	9 V	-5 V	Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	85 °C (185 °F)	2.8 V	Parallel, Word	-40 °C (-40 °F)	Matte Tin		Quad		S-PQCC-J44	3	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e3		245 °C (473 °F)	0.653 in (16.585 mm)
MX7578KP-T	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Commercial	J Bend	28	QCCJ	Square	Plastic/Epoxy	1	Yes	5 V		1	CMOS	12			5 V	Binary	±5,15 V	-5 V	Chip Carrier	LDCC28,.5SQ	Analog to Digital Converters	0.05 in (1.27 mm)	70 °C (158 °F)	0 mV	Parallel, 8 Bits	0 °C (32 °F)	Tin Lead		Quad	150 µs	S-PQCC-J28	1	0.18 in (4.57 mm)	0.453 in (11.505 mm)	No	e0			0.453 in (11.505 mm)
MAX181BEQH-TD	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Industrial	J Bend	44	QCCJ	Square	Plastic/Epoxy	8	Yes	2.5 V	100 kHz	1		12		0.0244 %	5 V	Binary	5,-12/-15 V	-12 V	Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	85 °C (185 °F)	-2.5 V	Parallel, Word	-40 °C (-40 °F)	Tin Lead	Track	Quad	10 µs	S-PQCC-J44		0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e0			0.653 in (16.585 mm)
MAX138CQH-TD	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Commercial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	200 mV		1	CMOS	24		0.05 %	5 V	Binary	5 V		Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	70 °C (158 °F)		Parallel, Word	0 °C (32 °F)	Tin Lead		Quad		S-PQCC-J44		0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e0			0.653 in (16.585 mm)
MX674AJP-T	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Commercial	J Bend	28	HQCCJ	Square	Plastic/Epoxy	1	Yes	10 V		1	BICMOS	12		0.0244 %	15 V	Offset Binary		-15 V	Chip Carrier, Heat Sink/Slug			0.05 in (1.27 mm)	70 °C (158 °F)	-10 V	Parallel, Word	0 °C (32 °F)		Sample	Quad	15 µs	S-PQCC-J28		0.18 in (4.57 mm)	0.453 in (11.505 mm)					0.453 in (11.505 mm)
MX674AJP	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Commercial	J Bend	28	HQCCJ	Square	Plastic/Epoxy	1	Yes	10 V		1	BICMOS	12		0.0244 %	15 V	Offset Binary		-15 V	Chip Carrier, Heat Sink/Slug			0.05 in (1.27 mm)	70 °C (158 °F)	-10 V	Parallel, Word	0 °C (32 °F)		Sample	Quad	15 µs	S-PQCC-J28		0.18 in (4.57 mm)	0.453 in (11.505 mm)					0.453 in (11.505 mm)
MX674AKP-T	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Commercial	J Bend	28	HQCCJ	Square	Plastic/Epoxy	1	Yes	10 V		1	BICMOS	12		0.0122 %	15 V	Offset Binary		-15 V	Chip Carrier, Heat Sink/Slug			0.05 in (1.27 mm)	70 °C (158 °F)	-10 V	Parallel, Word	0 °C (32 °F)		Sample	Quad	15 µs	S-PQCC-J28		0.18 in (4.57 mm)	0.453 in (11.505 mm)					0.453 in (11.505 mm)
MX7582KP+	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Commercial	J Bend	28	QCCJ	Square	Plastic/Epoxy	4	Yes	5 V		1	CMOS	12	7.5 mA		15 V	Binary	±5,15 V	-5 V	Chip Carrier	LDCC28,.5SQ	Analog to Digital Converters	0.05 in (1.27 mm)	70 °C (158 °F)	0 mV	Parallel, 8 Bits	0 °C (32 °F)	Matte Tin		Quad	150 µs	S-PQCC-J28	1	0.18 in (4.57 mm)	0.453 in (11.5062 mm)	No	e3			0.453 in (11.5062 mm)
MAX131ACQH+D	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Industrial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	2 V		1	CMOS	16		0.0015 %	9 V	Binary	9 V		Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	85 °C (185 °F)	200 mV	Parallel, Word	-40 °C (-40 °F)	Matte Tin		Quad		S-PQCC-J44	3	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e3		245 °C (473 °F)	0.653 in (16.585 mm)
MAX131CQH+TD	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Industrial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	2 V		1	CMOS	16		0.0015 %	9 V	Binary	9 V		Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	85 °C (185 °F)	200 mV	Parallel, Word	-40 °C (-40 °F)	Matte Tin		Quad		S-PQCC-J44	3	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e3			0.653 in (16.585 mm)
MAX181CEQH-D	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Industrial	J Bend	44	QCCJ	Square	Plastic/Epoxy	8	Yes	2.5 V	100 kHz	1		12		0.0244 %	5 V	Binary	5,-12/-15 V	-12 V	Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	85 °C (185 °F)	-2.5 V	Parallel, Word	-40 °C (-40 °F)	Tin Lead	Track	Quad	10 µs	S-PQCC-J44	1	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e0			0.653 in (16.585 mm)
MAX130CQH-D	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Industrial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	2 V		1	CMOS	16		0.0015 %	9 V	Binary	9 V		Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	85 °C (185 °F)	200 mV	Parallel, Word	-40 °C (-40 °F)	Tin Lead		Quad		S-PQCC-J44	1	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e0			0.653 in (16.585 mm)
MX7828KP	Maxim Integrated	Analog To Digital Converter, Flash Method	Commercial	J Bend	28	QCCJ		Plastic/Epoxy	8	Yes	5.25 V		1	CMOS	8			5 V	Complementary Offset Binary			Chip Carrier				70 °C (158 °F)	0 mV	Parallel, 8 Bits	0 °C (32 °F)	Tin/Lead	Track	Quad	2.4 µs		1			No	e0
MX574ALP+T	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Commercial	J Bend	28	QCCJ	Square	Plastic/Epoxy	1	Yes	10 V		1	BICMOS	12		0.012 %	15 V	Binary, Offset Binary		-15 V	Chip Carrier			0.05 in (1.27 mm)	70 °C (158 °F)	-10 V	Parallel, Word	0 °C (32 °F)	Matte Tin		Quad	25 µs	S-PQCC-J28	1	0.18 in (4.57 mm)	0.453 in (11.505 mm)	No	e3	30 s	245 °C (473 °F)	0.453 in (11.505 mm)
MAX180ACQH-D	Maxim Integrated	Analog To Digital Converter, Successive Approximation	Commercial	J Bend	44	QCCJ	Square	Plastic/Epoxy	8	Yes	2.5 V	100 kHz	1		12		0.0244 %	5 V	Binary	5,-12/-15 V	-12 V	Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	70 °C (158 °F)	-2.5 V	Parallel, Word	0 °C (32 °F)	Tin Lead	Track	Quad	10 µs	S-PQCC-J44	1	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e0			0.653 in (16.585 mm)
MAX134EQH+D	Maxim Integrated	Analog To Digital Converter, Proprietary Method	Industrial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	3.3 V		1	Bipolar	4		1 %	5 V	9's Complement Binary Coded Decimal	9 V	-5 V	Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	85 °C (185 °F)	2.8 V	Parallel, Word	-40 °C (-40 °F)	Matte Tin		Quad		S-PQCC-J44	3	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e3		245 °C (473 °F)	0.653 in (16.585 mm)
ICL7126CQH-D	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Commercial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	2 V		1	CMOS	16		0.0015 %	9 V	Binary	9 V		Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	70 °C (158 °F)		Parallel, Word	0 °C (32 °F)	Tin Lead		Quad		S-PQCC-J44	1	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e0			0.653 in (16.585 mm)
MAX1172CBH-T	Maxim Integrated	Analog To Digital Converter, Flash/Successive Approximation	Commercial	J Bend	44	QCCJ	Square	Ceramic, Metal-Sealed Cofired	1	Yes	2 V	30 MHz	1	CMOS	12	150 mA		5 V	Binary		-5.2 V	Chip Carrier				70 °C (158 °F)	-2 V	Parallel, Word	0 °C (32 °F)	Tin Lead	Track	Quad		S-CQCC-J44				No	e0
MAX7129CQH+TD	Maxim Integrated	Analog To Digital Converter, Dual-Slope	Commercial	J Bend	44	QCCJ	Square	Plastic/Epoxy	1	Yes	2 V		1	CMOS	4			9 V	Binary	9 V		Chip Carrier	LDCC44,.7SQ	Analog to Digital Converters	0.05 in (1.27 mm)	70 °C (158 °F)	-3 V	Parallel, Word	0 °C (32 °F)	Matte Tin		Quad		S-PQCC-J44	3	0.18 in (4.57 mm)	0.653 in (16.585 mm)	No	e3			0.653 in (16.585 mm)

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.