DIE Voltage References 11

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Part	Manufacturer	Other IC type	Temperature Grade	No. of Terminals	Package Code	Package Shape	Surface Mount	Total Dose (V)	Package Body Material	Trim or Adjustable Output (V)	No. of Functions	Technology	Terminal Form	Maximum Voltage Tolerance	Package Style (Meter)	Package Equivalence Code	Sub-Category	Maximum Operating Temperature	Minimum Output Voltage	Minimum Operating Temperature	Max Voltage Temp Coef	Maximum Output Voltage	Terminal Position	JESD-30 Code	Moisture Sensitivity Level (MSL)	Maximum Supply Voltage (Vsup)	Width (mm)	Qualification	Minimum Supply Voltage (Vsup)	Additional Features	Maximum Time At Peak Reflow Temperature (s)	No. of Outputs	Peak Reflow Temperature (C)	Length	Nominal Output Voltage
REF5025SKGD2	Texas Instruments	THREE TERMINAL VOLTAGE REFERENCE	MILITARY	12	DIE	RECTANGULAR	YES		UNSPECIFIED	YES	1		NO LEAD	.14 %	UNCASED CHIP	DIE OR CHIP	Voltage References	210 Cel	2.4965 V	-55 Cel	3 ppm/Cel	2.5035 V	UPPER	R-XUUC-N12		18 V	1.676 mm	Not Qualified	3.25 V	INPUT VOLTAGE MAX:18V	NOT SPECIFIED	1	NOT SPECIFIED	2.04 mm	2.5 V
REF5025SKGD1	Texas Instruments	THREE TERMINAL VOLTAGE REFERENCE	MILITARY	12	DIE	RECTANGULAR	YES		UNSPECIFIED	YES	1		NO LEAD	.14 %	UNCASED CHIP	DIE OR CHIP	Voltage References	210 Cel		-55 Cel	3 ppm/Cel		UPPER	R-XUUC-N12		18 V		Not Qualified	3.25 V		NOT SPECIFIED	1	NOT SPECIFIED		2.5 V
LT1009MKGD1	Texas Instruments	TWO TERMINAL VOLTAGE REFERENCE	MILITARY	12	DIE	RECTANGULAR	YES		UNSPECIFIED	YES	1	BIPOLAR	NO LEAD	1.5 %	UNCASED CHIP	DIE OR CHIP	Voltage References	125 Cel	2.49 V	-55 Cel	35 ppm/Cel	2.51 V	UPPER	R-XUUC-N12	1		1.24 mm	Not Qualified				1		1.336 mm	2.5 V
TL431TDA2	Texas Instruments	THREE TERMINAL VOLTAGE REFERENCE		4	DIE	RECTANGULAR	YES		UNSPECIFIED	YES	1		NO LEAD		UNCASED CHIP						92 ppm/Cel		UPPER	R-XUUC-N4			25.8851 mm				NOT SPECIFIED	1	NOT SPECIFIED	25.9639 mm	2.495 V
TL431TDA1	Texas Instruments	THREE TERMINAL VOLTAGE REFERENCE		4	DIE	RECTANGULAR	YES		UNSPECIFIED	YES	1		NO LEAD		UNCASED CHIP						92 ppm/Cel		UPPER	R-XUUC-N4			25.8851 mm				NOT SPECIFIED	1	NOT SPECIFIED	25.9639 mm	2.495 V
REF3140TDD1	Texas Instruments	THREE TERMINAL VOLTAGE REFERENCE	COMMERCIAL	8	DIE	RECTANGULAR	YES		UNSPECIFIED	NO	1		NO LEAD		UNCASED CHIP			70 Cel		0 Cel			UPPER	R-XUUC-N8		5.5 V			4.146 V		NOT SPECIFIED	1	NOT SPECIFIED
REF3140TDD2	Texas Instruments	THREE TERMINAL VOLTAGE REFERENCE	COMMERCIAL	8	DIE	RECTANGULAR	YES		UNSPECIFIED	NO	1		NO LEAD		UNCASED CHIP			70 Cel		0 Cel			UPPER	R-XUUC-N8		5.5 V			4.146 V		NOT SPECIFIED	1	NOT SPECIFIED
REF3325ATDD1	Texas Instruments	THREE TERMINAL VOLTAGE REFERENCE	COMMERCIAL	8	DIE	RECTANGULAR	YES		UNSPECIFIED	NO	1		NO LEAD		UNCASED CHIP			70 Cel		0 Cel	30 ppm/Cel		UPPER	R-XUUC-N8		5.5 V			2.7 V		NOT SPECIFIED	1	NOT SPECIFIED
REF3325ATDD2	Texas Instruments	THREE TERMINAL VOLTAGE REFERENCE	COMMERCIAL	8	DIE	RECTANGULAR	YES		UNSPECIFIED	NO	1		NO LEAD		UNCASED CHIP			70 Cel		0 Cel	30 ppm/Cel		UPPER	R-XUUC-N8		5.5 V			2.7 V		NOT SPECIFIED	1	NOT SPECIFIED
TL1431VTDB1	Texas Instruments	TWO TERMINAL VOLTAGE REFERENCE		3	DIE	RECTANGULAR	YES	100k Rad(Si)	UNSPECIFIED	YES	1		NO LEAD		UNCASED CHIP						114 ppm/Cel		UPPER	R-XUUC-N3			1.1176 mm				NOT SPECIFIED	1	NOT SPECIFIED	1.6205 mm
TL1431VTDB2	Texas Instruments	TWO TERMINAL VOLTAGE REFERENCE		3	DIE	RECTANGULAR	YES	100k Rad(Si)	UNSPECIFIED	YES	1		NO LEAD		UNCASED CHIP						114 ppm/Cel		UPPER	R-XUUC-N3			1.1176 mm				NOT SPECIFIED	1	NOT SPECIFIED	1.6205 mm

Voltage References

Voltage references are electronic devices used to provide a stable, precise voltage output that is independent of changes in temperature, load, or input voltage. They are used in a wide range of electronic applications, including instrumentation, data acquisition systems, and power supplies.

Voltage references are typically designed to output a fixed voltage value, such as 2.5V or 5V, and can be based on various technologies, including zener diodes, bandgap references, and temperature-compensated voltage references.

Zener diode-based voltage references work by using the reverse breakdown voltage of a zener diode to generate a stable reference voltage. Bandgap references use the voltage difference between two junctions in a bipolar transistor to generate a stable voltage reference. Temperature-compensated voltage references use a combination of circuit elements to compensate for temperature changes and provide a stable voltage output.

Voltage references typically have a high level of accuracy and low drift over time, making them suitable for use in precision applications. They may also include features such as low power consumption, low noise, and short-circuit protection.