LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages General Description The LM4050/LM4051 are precision two-terminal, shuntmode, bandgap voltage references available in fixed reverse breakdown voltages of 1.225V, 2.048V, 2.500V, 3.000V, 3.3V, 4.096V, and 5.000V. Ideal for space-critical applications, the LM4050/LM4051 are offered in the subminiature 3-pin SC70 surface-mount packages (1.8mm x 1.8mm), 50% smaller than comparable devices in SOT23 surface-mount package (SOT23 versions are also available). Laser-trimmed resistors ensure excellent initial accuracy. With a 50ppm/C temperature coefficient, these devices are offered in three grades of initial accuracy ranging from 0.1% to 0.5%. The LM4050/LM4051 have a 60A to 15mA shunt-current capability with low dynamic impedance, ensuring stable reverse breakdown voltage accuracy over a wide range of operating temperatures and currents. The LM4050/LM4051 do not require an external stabilizing capacitor while ensuring stability with any capacitive loads. The LM4050/LM4051 specifications are guaranteed over the temperature range of -40C to +125C. Features o 50ppm/C (max) Temperature Coefficient Guaranteed over the -40C to +125C Temperature Range o Ultra-Small 3-Pin SC70 Package o 0.1% (max) Initial Accuracy o Wide Operating Current Range: 60A to 15mA o Low 28VRMS Output Noise (10Hz to 10kHz) o 1.225V, 2.048V, 2.500V, 3.000V, 3.3V, 4.096V, and 5.000V Fixed Reverse Breakdown Voltages o No Output Capacitors Required o Tolerates Capacitive Loads Pin Configuration TOP VIEW + + 1 ________________________Applications LM4050/ LM4051 Portable, Battery-Powered Equipment 3 N.C.* - 2 Notebook Computers Cell Phones SC70/SOT23 Industrial Process Controls *PIN 3 MUST BE LEFT UNCONNECTED OR CONNECTED TO PIN 2. Typical Operating Circuit Ordering Information appears at end of data sheet. VS ISHUNT + ILOAD RS ILOAD VR ISHUNT LM4050 For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim's website at www.maximintegrated.com. 19-2563; Rev 7; 1/13 LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages ABSOLUTE MAXIMUM RATINGS Reverse Current (cathode to anode) ..................................20mA Forward Current (anode to cathode) ..................................10mA Continuous Power Dissipation (TA = +70C) 3-Pin SC70 (derate 2.17mW/C above +70C) ............174mW 3-Pin SOT23 (derate 4.01mW/C above +70C)..........320mW Operating Temperature Range LM4050/LM4051_E_ _ _ ................................-40C to +125C Storage Temperature Range .............................-65C to +150C Junction Temperature ......................................................+150C Lead Temperature (soldering, 10s)..................................+300C Soldering Temperature (reflow) .......................................+260C Stresses beyond those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS--1.225V (IR = 100A, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) (Note 1) PARAMETER Reverse Breakdown Voltage Reverse Breakdown Voltage Tolerance (Note 2) Minimum Operating Current Average Reverse Voltage Temperature Coefficient (Notes 2, 3) SYMBOL VR VRTOL MIN TYP MAX LM4051A (0.1%) 1.2238 1.2250 1.2262 LM4051B (0.2%) 1.2226 1.2250 1.2275 LM4051C (0.5%) 1.2189 1.2250 1.2311 LM4051A 1.2 7 LM4051B 2.4 9 LM4051C 6.0 12 45 60 A IR = 10mA IR = 1mA 20 15 50 ppm/C IR = 100A 15 IRMIN IR 1mA 0.7 1.5 1mA IR 12mA 2.5 8.0 1.5 TA = +25C IRMIN VR/T Reverse Breakdown Voltage Change with Operating Current Change UNITS V mV mV Reverse Dynamic Impedance (Note 3) ZR IR = 1mA, f = 120Hz, IAC = 0.1IR 0.5 Wideband Noise eN IR = 100A, 10Hz f 10kHz 20 VRMS T = 1000h 120 ppm Reverse Breakdown Voltage Long-Term Stability 2 CONDITIONS VR Maxim Integrated LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages ELECTRICAL CHARACTERISTICS--2.048V (IR = 100A, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) (Note 1) PARAMETER Reverse Breakdown Voltage Reverse Breakdown Voltage Tolerance (Note 2) Minimum Operating Current Average Reverse Voltage Temperature Coefficient (Notes 2, 3) SYMBOL VR VRTOL CONDITIONS TA = +25C MIN TYP MAX LM4050A (0.1%) 2.0460 2.0480 2.0500 LM4050B (0.2%) 2.0439 2.0480 2.0521 LM4050C (0.5%) 2.0378 Reverse Breakdown Voltage Change with Operating Current Change V 2.0480 2.0582 LM4050A 2.0 12 LM4050B 4.0 14 LM4050C 10 20 45 65 A IR = 10mA IR = 1mA 20 15 50 ppm/C IR = 100A 15 IRMIN IR 1mA 0.3 1.0 1mA IR 15mA 2.5 8.0 LM4050A/B 0.3 0.8 LM4050C 0.3 0.9 IRMIN VR/T UNITS mV mV Reverse Dynamic Impedance (Note 3) ZR IR = 1mA, f = 120Hz, IAC = 0.1IR Wideband Noise eN IR = 100A, 10Hz f 10kHz 28 VRMS T = 1000h 120 ppm Reverse Breakdown Voltage Long-Term Stability Maxim Integrated VR 3 LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages ELECTRICAL CHARACTERISTICS--2.500V (IR = 100A, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) (Note 1) PARAMETER Reverse Breakdown Voltage SYMBOL VR Reverse Breakdown Voltage Tolerance (Note 2) VRTOL Minimum Operating Current IRMIN Average Reverse Voltage Temperature Coefficient (Notes 2, 3) VR/T Reverse Breakdown Voltage Change with Operating Current Change MIN TYP MAX LM4050A (0.1%) 2.4975 2.5000 2.5025 LM4050B (0.2%) 2.4950 2.5000 2.5050 LM4050C (0.5%) 2.4875 2.5000 2.5125 LM4050A 2.5 15 LM4050B 5.0 18 LM4050C 13 25 45 65 A 50 ppm/C TA = +25C IR = 10mA 20 IR = 1mA 15 IR = 100A 15 IRMIN IR 1mA 0.3 1.0 1mA IR 15mA 2.5 8.0 LM4050A/B 0.3 0.8 LM4050C 0.3 0.9 UNITS V mV mV Reverse Dynamic Impedance (Note 3) ZR IR = 1mA, f = 120Hz, IAC = 0.1IR Wideband Noise eN IR = 100A, 10Hz f 10kHz 35 VRMS T = 1000h 120 ppm Reverse Breakdown Voltage Long-Term Stability 4 CONDITIONS VR Maxim Integrated LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages ELECTRICAL CHARACTERISTICS--3.000V (IR = 100A, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) (Note 1) PARAMETER Reverse Breakdown Voltage Reverse Breakdown Voltage Tolerance (Note 2) Minimum Operating Current Average Reverse Voltage Temperature Coefficient (Notes 2, 3) SYMBOL VR VRTOL CONDITIONS MIN TYP MAX LM4050A (0.1%) 2.9970 3.0000 3.0030 LM4050B (0.2%) 2.9940 3.0000 3.0060 LM4050C (0.5%) 2.9850 3.0000 3.0150 LM4050A 3.0 18 LM4050B 6.0 21 LM4050C 15 30 45 67 A IR = 10mA 20 IR = 1mA 15 50 ppm/C IR = 100A 15 IRMIN IR 1mA 0.3 1.0 1mA IR 15mA 2.5 8.0 LM4050A/B 0.3 0.8 LM4050C 0.3 0.9 TA = +25C IRMIN VR/T Reverse Breakdown Voltage Change with Operating Current Change UNITS V mV mV Reverse Dynamic Impedance (Note 3) ZR IR = 1mA, f = 120Hz, IAC = 0.1IR Wideband Noise eN IR = 100A, 10Hz f 10kHz 45 VRMS T = 1000h 120 ppm Reverse Breakdown Voltage Long-Term Stability VR ELECTRICAL CHARACTERISTICS--3.300V (IR = 100A, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) (Note 1) PARAMETER Reverse Breakdown Voltage Reverse Breakdown Voltage Tolerance (Note 2) Minimum Operating Current Average Reverse Voltage Temperature Coefficient (Notes 2, 3) SYMBOL VR VRTOL CONDITIONS MIN TYP MAX LM4050A (0.1%) 3.2967 3.3000 3.3033 LM4050B (0.2%) 3.2934 3.3000 3.3066 LM4050C (0.5%) 3.2835 3.3000 3.3165 LM4050A 3.0 18 LM4050B 6.0 21 LM4050C 15 30 45 67 A IR = 10mA 20 IR = 1mA 15 50 ppm/C IR = 100A 15 IRMIN IR 1mA 0.3 1.0 1mA IR 15mA 2.5 8.0 LM4050A/B 0.3 0.8 LM4050C 0.3 0.9 TA = +25C IRMIN VR/T Reverse Breakdown Voltage Change with Operating Current Change UNITS V mV mV Reverse Dynamic Impedance (Note 3) ZR IR = 1mA, f = 120Hz, IAC = 0.1IR Wideband Noise eN IR = 100A, 10Hz f 10kHz 50 VRMS T = 1000h 120 ppm Reverse Breakdown Voltage Long-Term Stability Maxim Integrated VR 5 LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages ELECTRICAL CHARACTERISTICS--4.096V (IR = 100A, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) (Note 1) PARAMETER Reverse Breakdown Voltage Reverse Breakdown Voltage Tolerance (Note 2) Minimum Operating Current Average Reverse Voltage Temperature Coefficient (Notes 2, 3) SYMBOL VR VRTOL MIN TYP MAX LM4050A (0.1%) 4.0919 4.0960 4.1001 LM4050B (0.2%) 4.0878 4.0960 4.1042 LM4050C (0.5%) 4.0755 4.0960 4.1165 LM4050A 4.1 25 LM4050B 8.2 29 LM4050C 20 41 50 73 A IR = 10mA 30 IR = 1mA 20 50 ppm/C IR = 100A 15 IRMIN IR 1mA 0.5 1.2 1mA IR 15mA 3.0 10.0 1.0 TA = +25C IRMIN VR/T Reverse Breakdown Voltage Change with Operating Current Change UNITS V mV mV Reverse Dynamic Impedance (Note 3) ZR IR = 1mA, f = 120Hz, IAC = 0.1IR 0.5 Wideband Noise eN IR = 100A, 10Hz f 10kHz 64 VRMS T = 1000h 120 ppm Reverse Breakdown Voltage Long-Term Stability 6 CONDITIONS VR Maxim Integrated LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages ELECTRICAL CHARACTERISTICS--5.000V (IR = 100A, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C.) (Note 1) PARAMETER Reverse Breakdown Voltage SYMBOL VR Reverse Breakdown Voltage Tolerance (Note 2) VRTOL Minimum Operating Current IRMIN Average Reverse Voltage Temperature Coefficient (Notes 2, 3) VR/T Reverse Breakdown Voltage Change with Operating Current Change CONDITIONS TA = +25C MIN TYP MAX LM4050A (0.1%) 4.9950 5.0000 5.0050 LM4050B (0.2%) 4.9900 5.0000 5.0100 LM4050C (0.5%) 4.9750 UNITS V 5.0000 5.0250 LM4050A 5.0 30 LM4050B 10 35 LM4050C 25 50 54 80 A 50 ppm/C IR = 10mA 30 IR = 1mA 20 IR = 100A 15 IRMIN IR 1mA 0.5 1.4 1mA IR 15mA 3.5 12.0 1.1 mV mV Reverse Dynamic Impedance (Note 3) ZR IR = 1mA, f = 120Hz, IAC = 0.1IR 0.5 Wideband Noise eN IR = 100A, 10Hz f 10kHz 80 VRMS T = 1000h 120 ppm Reverse Breakdown Voltage Long-Term Stability VR Note 1: All devices are 100% production tested at +25C and are guaranteed by design for TA = TMIN to TMAX, as specified. Note 2: The limit over the full temperature range for the reverse breakdown voltage tolerance is defined as: [VRTOL] [(VR / T) X (maxT) X (VR)] where VR / T is the VR temperature coefficient, maxT is the difference from the +25C reference point to TMIN or TMAX, and VR is the reverse breakdown voltage. The total tolerance over the full temperature range for the different grades where maxT = +100C is shown below: * A grade: 0.6% = 0.1% 50ppm/C 100C * B grade: 0.7% = 0.2% 50ppm/C 100C * C grade: 1.0% = 0.5% 50ppm/C 100C Note 3: Guaranteed by design. Maxim Integrated 7 LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages Typical Operating Characteristics (IR = 100A, SC70-3 package, TA = +25C, unless otherwise noted.) OUTPUT VOLTAGE vs. TEMPERATURE (VOUT = 2.500V) OUTPUT VOLTAGE (V) 4 LM4050_I_3-3.0 3 2 MAX4050 toc02 5.001 2.494 2.492 LM4050_I_3-2.5 1 2.496 4.995 4.993 4.989 2.490 0 50 4.987 -40 100 -15 10 35 60 85 110 135 -40 -15 TEMPERATURE (C) REVERSE CURRENT (A) TA = -40C TA = +25C TA = +85C 2 1 6 REVERSE VOLTAGE CHANGE (mV) LM4050 toc04 TA = +125C 3 35 60 85 110 135 LM4050-5.0V REVERSE VOLTAGE vs. ISHUNT 5 4 10 TEMPERATURE (C) LM4050-2.5V REVERSE VOLTAGE vs. ISHUNT REVERSE VOLTAGE CHANGE (mV) 4.997 4.991 LM4050_I_3-2.1 0 4.999 LM4050 toc05 REVERSE VOLTAGE (V) 5 5.003 OUTPUT VOLTAGE (V) LM4050_I_3-5.0 LM4050_I_3-4.1 2.498 LM4050 toc01 6 OUTPUT VOLTAGE vs. TEMPERATURE (VOUT = 5.000V) MAX4050 toc03 REVERSE CHARACTERISTICS AND MINIMUM OPERATING CURRENT TA = -40C 5 4 TA = +125C 3 TA = +85C 2 1 TA = +25C 0 0 0 5 10 ISHUNT (mA) 8 15 20 0 5 10 15 20 ISHUNT (mA) Maxim Integrated LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages Typical Operating Characteristics (continued) (IR = 100A, SC70-3 package, TA = +25C, unless otherwise noted.) LM4050-5.0V LOAD-TRANSIENT RESPONSE LM4050-2.5V LOAD-TRANSIENT RESPONSE LM4050-2.5V LOAD-TRANSIENT RESPONSE LM4050 toc07 LM4050 toc06 LM4050 toc08 +25A VGEN -25A VR AC-COUPLED VR AC-COUPLED -25A 2mV/div 10mV/div 10mV/div 10s/div ISHUNT = 100A 25A RL = 100k, SEE FIGURE 1. ISHUNT = 1mA 250A RL = 10k, SEE FIGURE 1. LM4050-2.5V LOAD-TRANSIENT RESPONSE LM4050-5.0V LOAD-TRANSIENT RESPONSE LM4050-5.0V LOAD-TRANSIENT RESPONSE LM4050 toc10 LM4050 toc09 LM4050 toc11 +2.5mA VGEN -2.5mA VR AC-COUPLED -250A 10mV/div +2.5mA 20mV/div 10s/div 10s/div -2.5mA VR AC-COUPLED VGEN VGEN +250A VR AC-COUPLED -250A 40s/div 10s/div CH1: VGEN 2V/div CH2: VR AC-COUPLED 2mV/div ISHUNT = 100A 25A, RL = 100k, SEE FIGURE 1. ISHUNT = 1mA 250A RL = 10k, SEE FIGURE 1. +250A VR AC-COUPLED VGEN VGEN +25A 20mV/div 10s/div ISHUNT = 10mA 2.5mA RL = 1k, SEE FIGURE 1. ISHUNT = 10mA 2.5mA RL = 1k, SEE FIGURE 1. ISHUNT VB 1k + - RL VR VGEN Figure 1. Load-Transient Test Circuit Maxim Integrated 9 LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages Typical Operating Characteristics (continued) (IR = 100A, SC70-3 package, TA = +25C, unless otherwise noted.) LM4050 toc13 5V 1000 5V VIN VIN C1 = 1F 0 2V 4V 1V 0 100 IMPEDANCE () 0 VOUT VOUT LM4050-2.5V OUTPUT IMPEDANCE vs. FREQUENCY LM4050-5.0V STARTUP CHARACTERISTICS LM4050 toc12 LM4050 toc14 LM4050-2.5V STARTUP CHARACTERISTICS 2V IR = 150A 10 C1 = 0 1 0 IR = 1mA RS = 30k 4 RS = 16k 8 12 16 20 24 28 32 36 0 RESPONSE TIME (s) SEE FIGURE 2. 10k 100k LM4050-2.5V NOISE vs. FREQUENCY LM4050-5.0V NOISE vs. FREQUENCY NOISE (nV/Hz) IR = 150A 10,000 IR = 1mA 10,000 NOISE (nV/Hz) C1 = 0 IMPEDANCE () 1k FREQUENCY (Hz) LM4050 toc16 LM4050 toc15 100 1 0.1k RESPONSE TIME (s) 1M SEE FIGURE 2. LM4050-5.0V OUTPUT IMPEDANCE vs. FREQUENCY 10 0.1 10 20 30 40 50 60 70 80 90 1000 LM4050 toc17 0 1000 C1 = 1F 100 0.1 0.1k 1k 10k 100k 1M 100 1 10 100 1k 10k FREQUENCY (Hz) FREQUENCY (Hz) 1 10 100 1k 10k FREQUENCY (Hz) RS VIN 1Hz RATE 50% DUTY CYCLE VR Figure 2. Startup Characteristics Test Circuit 10 Maxim Integrated LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages Pin Description PIN NAME FUNCTION 1 + Positive Terminal of the Shunt Reference 2 - Negative Terminal of the Shunt Reference 3 N.C. No connection. Leave this pin unconnected or connected to pin 2. Detailed Description The LM4050/LM4051 shunt references use the bandgap principle to produce a stable, accurate voltage. The device behaves similarly to an ideal zener diode; a fixed voltage is maintained across its output terminals when biased with 60A to 15mA of reverse current. The LM4050/LM4051 clamps to a voltage of one diode drop below ground when biased with forward currents up 10mA. Figure 3 shows a typical operating circuit. The LM4050/LM4051 are ideal for providing stable references from a high-voltage power supply. Applications Information The LM4050/LM4051s' internal pass transistors are used to maintain a constant output voltage (VSHUNT) by sinking the necessary amount of current across a source resistor. The source resistance (RS) is determined from the load current (ILOAD) range, supply voltage (VS) variations, VSHUNT, and desired quiescent current. Choose the value of RS when VS is at a minimum and ILOAD is at a maximum. Maintain a minimum ISHUNT of 60A at all times. The RS value should be large enough to keep ISHUNT less than 15mA for proper regulation when VS is maximum and ILOAD is at a minimum. To prevent damage to the device, ISHUNT should never exceed 20mA. Therefore, the value of RS is bounded by the following equation: [VS(MIN) - VR ] / [60A + ILOAD(MAX)] > RS > [VS(MAX) - VR ] / [20mA + ILOAD(MIN)] Choosing a larger resistance minimizes the total power dissipation in the circuit by reducing the shunt current (PD(TOTAL) = VS ISHUNT). Provide a safety margin to incorporate the worst-case tolerance of the resistor used. Ensure that the resistor's power rating is adequate, using the following general power equation: PDR = ISHUNT (VS(MAX) - VSHUNT) Output Capacitance VS ISHUNT + ILOAD RS ILOAD VR ISHUNT LM4050 Figure 3. Typical Operating Circuit Temperature Performance The LM4050/LM4051 typically exhibit output voltage temperature coefficients within 15ppm/C. The polarity of the temperature coefficients may be different from one device to another; some may have positive coefficients, and others may have negative coefficients. High Temperature Operation The maximum junction temperature of the LM4050/ LM4051 is +150C. The maximum operating temperature for the LM4050/LM4051_E_ is +125C. At a maximum load current of 15mA and a maximum output voltage of 5V, the parts dissipate 75mW of power. The power dissipation limits of the 3-pin SC70 call for a derating value of 2.17mW/C above +70C and thus for 75mW of power dissipation, the parts self-heat to 35.56C above ambient temperature. If the ambient temperature is +125C, the parts operate at 159.56C, thereby exceeding the maximum junction temperature value of +150C. For hightemperature operation, care must be taken to ensure the combination of ambient temperature, output power dissipation, and package thermal resistance does not conspire to raise the device temperature beyond that listed in the Absolute Maximum Ratings. Either reduce the output load current or the ambient temperature to keep the part within the limits. The LM4050/LM4051 do not require external capacitors for frequency stability and are stable for any output capacitance. Maxim Integrated 11 LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages Ordering Information PART OUTPUT INITIAL VOLTAGE (V) ACCURACY (%) TEMPCO (ppm/_ C) TEMP RANGE PINPACKAGE TOP MARK LM4050AEM3-2.1+T 2.048 0.1 50 -40C to +125C 3 SOT23 LM4050AEX3-2.1+T 2.048 0.1 50 -40C to +125C 3 SC70 FZTR ASM LM4050BEM3-2.1+T 2.048 0.2 50 -40C to +125C 3 SOT23 FZTS LM4050BEX3-2.1+T 2.048 0.2 50 -40C to +125C 3 SC70 ASN LM4050CEM3-2.1+T 2.048 0.5 50 -40C to +125C 3 SOT23 FZTT LM4050CEX3-2.1+T 2.048 0.5 50 -40C to +125C 3 SC70 ASO LM4050AEM3-2.5+T 2.500 0.1 50 -40C to +125C 3 SOT23 FZTU LM4050AEX3-2.5+T 2.500 0.1 50 -40C to +125C 3 SC70 ASP LM4050AEX3-2.5/V+T 2.500 0.1 50 -40C to +125C 3 SC70 +AUE LM4050BEM3-2.5+T 2.500 0.2 50 -40C to +125C 3 SOT23 FZTV LM4050BEX3-2.5+T 2.500 0.2 50 -40C to +125C 3 SC70 ASQ LM4050CEM3-2.5+T 2.500 0.5 50 -40C to +125C 3 SOT23 FZTW LM4050CEX3-2.5+T 2.500 0.5 50 -40C to +125C 3 SC70 ASR LM4050AEM3-3.0+T 3.000 0.1 50 -40C to +125C 3 SOT23 FZTX LM4050AEX3-3.0+T 3.000 0.1 50 -40C to +125C 3 SC70 ASS LM4050BEM3-3.0+T 3.000 0.2 50 -40C to +125C 3 SOT23 FZTY LM4050BEM3-3.0/V+T 3.000 0.2 50 -40C to +125C 3 SOT23 +FZVG LM4050BEX3-3.0+T 3.000 0.2 50 -40C to +125C 3 SC70 AST LM4050CEM3-3.0+T 3.000 0.5 50 -40C to +125C 3 SOT23 FZTZ LM4050CEX3-3.0+T 3.000 0.5 50 -40C to +125C 3 SC70 ASU LM4050AEX3-3.3+T 3.300 0.1 50 -40C to +125C 3 SC70 AOJ LM4050AEX3-3.3/V+T 3.300 0.1 50 -40C to +125C 3 SC70 +AUE LM4050BEX3-3.3+T 3.300 0.2 50 -40C to +125C 3 SC70 AOK LM4050CEX3-3.3+T 3.300 0.5 50 -40C to +125C 3 SC70 AOL LM4050CEX3-3.3/V+T 3.300 0.5 50 -40C to +125C 3 SC70 +AUE LM4050AEM3-4.1+T 4.096 0.1 50 -40C to +125C 3 SOT23 FZUA LM4050AEX3-4.1+T 4.096 0.1 50 -40C to +125C 3 SC70 LM4050BEM3-4.1+T 4.096 0.2 50 -40C to +125C 3 SOT23 FZUB LM4050BEM3-4.1/V+T 4.096 0.2 50 -40C to +125C 3 SOT23 +FZVL LM4050BEX3-4.1+T 4.096 0.2 50 -40C to +125C 3 SC70 ASW LM4050CEM3-4.1+T 4.096 0.5 50 -40C to +125C 3 SOT23 FZUC LM4050CEX3-4.1+T 4.096 0.5 50 -40C to +125C 3 SC70 LM4050AEM3-5.0+T 5.000 0.1 50 -40C to +125C 3 SOT23 LM4050AEX3-5.0+T 5.000 0.1 50 -40C to +125C 3 SC70 LM4050BEM3-5.0+T 5.000 0.2 50 -40C to +125C 3 SOT23 LM4050BEX3-5.0+T 5.000 0.2 50 -40C to +125C 3 SC70 ASZ LM4050CEM3-5.0+T 5.000 0.5 50 -40C to +125C 3 SOT23 FZUF LM4050CEM3-5.0/V+T 5.000 0.5 50 -40C to +125C 3 SOT23 +FZVM LM4050CEX3-5.0+T 5.000 0.5 50 -40C to +125C 3 SC70 12 ASV ASX FZUD ASY FZUE ATA Maxim Integrated LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages Ordering Information (continued) PART OUTPUT INITIAL VOLTAGE (V) ACCURACY (%) TEMPCO (ppm/_ C) TEMP RANGE PINPACKAGE TOP MARK FZTO LM4051AEM3-1.2+T 1.225 0.1 50 -40C to +125C 3 SOT23 LM4051AEX3-1.2+T 0.1 50 -40C to +125C 3 SC70 ASJ LM4051BEM3-1.2+T 1.225 1.225 0.2 50 -40C to +125C 3 SOT23 FZTP LM4051BEX3-1.2+T 1.225 0.2 50 -40C to +125C 3 SC70 ASK LM4051CEM3-1.2+T 1.225 0.5 50 -40C to +125C 3 SOT23 FZTQ LM4051CEX3-1.2+T 1.225 0.5 50 -40C to +125C 3 SC70 Package Information Chip Information PROCESS: BiCMOS Maxim Integrated ASL For the latest package outline information and land patterns (footprints), go to www.maximintegrated.com/packages. Note that a "+", "#", or "-" in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. PACKAGE TYPE PACKAGE CODE OUTLINE NO. LAND PATTERN NO. 3 SOT23 U3+1 21-0051 90-0179 3 SC70 X3+2 21-0075 90-0208 13 LM4050/LM4051 50ppm/C Precision Micropower Shunt Voltage References with Multiple Reverse Breakdown Voltages Revision History REVISION NUMBER REVISION DATE 0 7/02 Initial release 4 5/09 Added lead-free notation and corrected topmarks in the Ordering Information and Selector Guide sections 1, 12 5 5/11 Added automotive packages and updated the Absolute Maximum Ratings. 1, 2 6 9/11 Added automotive packages to Selector Guide and Ordering Information. 1, 12 7 1/13 Removed Selector Guide and revised Ordering Information. 1, 12 DESCRIPTION PAGES CHANGED -- Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance. 14 ________________________________Maxim Integrated 160 Rio Robles, San Jose, CA 95134 USA 1-408-601-1000 (c) 2013 Maxim Integrated Products, Inc. Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc.