VRE302 Low Cost Precision Reference THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 85745 • (520) 882-4000 FEATURES • 2.500 V OUTPUT ± 0.250 mV (.01%) PIN CONFIGURATION • TEMPERATURE DRIFT: 0.6 ppm/°C • LOW NOISE: 1.5µV p-p (0.1-10Hz) • INDUSTRY STD PINOUT- 8 PIN DIP OR SURFACE MOUNT PACKAGE N.C. 1 +VIN 2 TEMP 3 GND 4 VRE302 TOP VIEW 8 NOISE 7 REF. GND 6 VOUT 5 TRIM •EXCELLENT LINE REGULATION: 6ppm/V Typ. • OUTPUT TRIM CAPABILITY FIGURE 1 DESCRIPTION The VRE302 is a low cost, high precision 2.5V reference. Packaged in the industry standard 8 pin DIP, the device is ideal for upgrading systems that use lower performance references. The device provides ultrastable +2.500V output with ±0.2500 mV (.01%) initial accuracy and a temperature coefficient of 0.6 ppm/°C. This improvement in accuracy is made possible by a unique, patented multipoint laser compensation technique developed by Thaler Corporation. Significant improvements have been made in other performance parameters as well, including initial accuracy, warm-up drift, line regulation, and long-term stability, making the VRE302 series the most accurate reference available in the standard 8 pin DIP package. For enhanced performance, the VRE302 has an external trim option for users who want less than 0.01% initial error. A reference ground pin is provided to eliminate socket contact resistance errors. The VRE302 is recommended for use as a reference for 14, 16, or 18 bit D/A converters which require an external precision reference. The device is also ideal for calibrating scale factor on high resolution A/D converters. The VRE302 offers superior performance over monolithic references. SELECTION GUIDE Model Initial Error mV VRE302A VRE302B VRE302C VRE302J VRE302K VRE302L 0.25 0.40 0.50 0.25 0.40 0.50 Temp. Coeff. ppm/°C 0.6 1.0 2.0 0.6 1.0 2.0 Temp. Range °C 0°C to +70°C 0°C to +70°C 0°C to +70°C -40°C to +85°C -40°C to +85°C -40°C to +85°C For package option add D for DIP or S for Surface Mount to end of model number. VRE302DS REV. F MAY 2001 ELECTRICAL SPECIFICATIONS VRE302 Vps =+15V, T = 25°C, RL = 10KΩ unless otherwise noted. MODEL A/J PARAMETER MIN TYP B/K MAX C/L MIN TYP MAX MIN TYP MAX UNITS * * * * * * * * * * * * * * * * * * V °C °C °C ABSOLUTE RATINGS Power Supply Operating Temp. (A,B,C) Operating Temp. (J,K,L) Storage Temperature Short Circuit Protection +13.5 +15 +22 0 +70 -40 +85 -65 +150 Continuous * * * * * * OUTPUT VOLTAGE VRE302 (1) Temp. Sensor Voltage 2.500 630 V mV OUTPUT VOLTAGE ERRORS (2) Initial Error Warmup Drift Tmin - Tmax (3) Long-Term Stability Noise (.1-10Hz) (4) 0.25 0.40 1 0.50 2 0.6 3 1.0 6 1.5 2.0 * * * * mV ppm ppm/°C ppm/1000hrs µVpp OUTPUT CURRENT Range ±10 * * mA REGULATION Line Load 6 3 10 * * * * * * ppm/V ppm/mA OUTPUT ADJUSTMENT Range 10 POWER SUPPLY CURRENTS * mV (5) VRE302 +PS NOTES: * 5 7 *Same as A/J Models. 1. The temp. reference TC is 2.1mV/ °C 2. The specified values are without external trim. * * * * mA 4. The specified values are without the external noise reduction capacitor. 5. The specified values are unloaded. 3. The temperature coefficient is determined by the box method using the following formula: Vmax - Vmin x 106 T.C. = Vnominal x (Tmax-Tmin) VRE302DS REV. F MAY 2001 TYPICAL PERFORMANCE CURVES VOUT vs. TEMPERATURE Temperature oC VRE302A VOUT vs. TEMPERATURE Temperature oC VRE302J VOUT vs. TEMPERATURE VOUT vs. TEMPERATURE Temperature oC VRE302B Temperature oC VRE302C VOUT vs. TEMPERATURE VOUT vs. TEMPERATURE Temperature oC VRE302K Temperature oC VRE302L POSITIVE OUTPUT (TYP) QUIESCENT CURRENT VS. TEMP JUNCTION TEMP. RISE VS. OUTPUT CURRENT Temperature oC Output Current (mA) PSRR VS. FREQUENCY Frequency (Hz) VRE302DS REV. F MAY 2001 DISCUSSION OF PERFORMANCE THEORY OF OPERATION The following discussion refers to the schematic in figure 2 below. A FET current source is used to bias a 6.3V zener diode. The zener voltage is divided by the resistor network R1 and R2. This voltage is then applied to the noninverting input of the operational amplifier which amplifies the voltage to produce a 2.500V output. The gain is determined by the resistor networks R3 and R4: G=1 + R4/R3. The 6.3V zener diode is used because it is the most stable diode over time and temperature. This network is less than 2% of the overall network resistance so it has a negligible effect on long term stability. Figure 3 shows the proper connection of the VRE302 series voltage references with the optional trim resistor for initial error. The VRE302 reference has the ground terminal brought out on two pins (pin 4 and pin 7) which are connected together internally. This allows the user to achieve greater accuracy when using a socket. Voltage references have a voltage drop across their power supply ground pin due to quiescent current flowing through the contact resistance. If the contact resistance was constant with time and temperature, this voltage drop could be trimmed out. When the reference is plugged into a socket, this source of error can be as high as 20ppm. By connecting pin 4 to the power supply ground and pin 7 to a high impedance ground point in the measurement circuit, the error due to the contact resistance can be eliminated. If the unit is soldered into place, the contact resistance is sufficiently small that it does not effect performance. Pay careful attention to the circuit layout to avoid noise pickup and voltage drops in the lines. The current source provides a closely regulated zener current, which determines the slope of the references’ voltage vs. temperature function. By trimming the zener current a lower drift over temperature can be achieved. But since the voltage vs. temperature function is nonlinear this compensation technique is not well suited for wide temperature ranges. Thaler Corporation has developed a nonlinear compensation network of thermistors and resistors that is used in the VRE series voltage references. This proprietary network eliminates most of the nonlinearity in the voltage vs. temperature function. By adjusting the slope, Thaler Corporation produces a very stable voltage over wide temperature ranges. VRE302 FIGURE 2 EXTERNAL CONNECTIONS + VIN V TEMP OUT 2 3 8 OPTIONAL NOISE REDUCTION CAPACITOR 6 VRE302 CN 1µF 5 7 FIGURE 3 + VOUT 4 10kΩ OPTIONAL FINE TRIM ADJUSTMENT REF. GND VRE302DS REV. F MAY 2001 MECHANICAL FIGURE 3 D D1 INCHES D2 E1 E2 PIN 1 IDENTIFIER E MILLIMETER MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 D2 .018 .023 0.46 0.58 B .098 .102 2.48 2.59 E .507 .513 12.8 13.0 B1 .046 .051 1.14 1.29 E1 .397 .403 10.0 10.2 C .107 .113 2.71 2.89 E2 .264 .270 6.70 6.85 C1 .009 .012 0.22 0.30 P .085 .095 2.15 2.41 C2 .052 .058 1.32 1.47 Q .020 .030 .508 .762 S .045 .055 1.14 1.39 D .397 .403 10.0 10.2 D1 .372 .380 9.44 9.65 E1 P BASE SEATING B MILLIMETER MIN Q A INCHES DIM C1 C2 C S B1 FIGURE 4 INCHES MILLIMETER INCHES MILLIMETER DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 E .397 .403 10.0 10.2 B .018 .022 .457 .558 E1 .264 .270 6.70 6.85 B1 .046 .051 1.14 1.29 G1 .290 .310 7.36 7.87 B2 .098 .102 2.48 2.59 L .195 .215 4.95 5.46 C .009 .012 0.22 0.30 P .085 .095 2.15 2.41 D .397 .403 10.0 10.2 Q .055 .065 1.39 1.65 D1 .372 .380 9.44 9.65 S .045 .055 1.14 1.39 VRE302DS REV. F MAY 2001 VRE302-6 Low Cost Precision Reference THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 85745 • (520) 882-4000 FEATURES • 2.048 V OUTPUT ± 0.205 mV (.01%) PIN CONFIGURATION • TEMPERATURE DRIFT: 0.6 ppm/°C • LOW NOISE: 1.5µV p-p (0.1-10Hz) • INDUSTRY STD PINOUT- 8 PIN DIP OR SURFACE MOUNT PACKAGE N.C. 1 +VIN 2 TEMP 3 GND 4 VRE302-6 TOP VIEW 8 NOISE 7 REF. GND 6 VOUT 5 TRIM •EXCELLENT LINE REGULATION: 6ppm/V Typ. • OUTPUT TRIM CAPABILITY FIGURE 1 DESCRIPTION The VRE302-6 is a low cost, high precision 2.5V reference. Packaged in the industry standard 8 pin DIP, the device is ideal for upgrading systems that use lower performance references. The device provides ultrastable +2.048V output with ±0.205 mV (.01%) initial accuracy and a temperature coefficient of 0.6 ppm/°C. This improvement in accuracy is made possible by a unique, patented multipoint laser compensation technique developed by Thaler Corporation. Significant improvements have been made in other performance parameters as well, including initial accuracy, warm-up drift, line regulation, and long-term stability, making the VRE302-6 series the most accurate reference available in the standard 8 pin DIP package. For enhanced performance, the VRE302-6 has an external trim option for users who want less than 0.01% initial error. A reference ground pin is provided to eliminate socket contact resistance errors. The VRE302-6 is recommended for use as a reference for 14, 16, or 18 bit D/A converters which require an external precision reference. The device is also ideal for calibrating scale factor on high resolution A/D converters. The VRE3026 offers superior performance over monolithic references. SELECTION GUIDE Model VRE302-6A VRE302-6B VRE302-6C VRE302-6J VRE302-6K VRE302-6L Initial Error mV Temp. Coeff. ppm/°C Temp. Range °C 0.20 0.35 0.40 0.20 0.35 0.40 0.6 1.0 2.0 0.6 1.0 2.0 0°C to +70°C 0°C to +70°C 0°C to +70°C -40°C to +85°C -40°C to +85°C -40°C to +85°C For package option add D for DIP or S for Surface Mount to end of model number. VRE302-6DS REV. B MAY 2001 ELECTRICAL SPECIFICATIONS VRE302-6 Vps =+15V, T = 25°C, RL = 10KΩ unless otherwise noted. MODEL A/J PARAMETER MIN TYP B/K MAX C/L MIN TYP MAX MIN TYP MAX UNITS * * * * * * * * * * * * * * * * * * V °C °C °C ABSOLUTE RATINGS Power Supply Operating Temp. (A,B,C) Operating Temp. (J,K,L) Storage Temperature Short Circuit Protection +13.5 +15 +22 0 +70 -40 +85 -65 +150 Continuous * * * * * * OUTPUT VOLTAGE VRE302-6 (1) Temp. Sensor Voltage 2.048 630 V mV OUTPUT VOLTAGE ERRORS (2) Initial Error Warmup Drift Tmin - Tmax (3) Long-Term Stability Noise (.1-10Hz) (4) 0.20 0.35 1 0.40 2 0.6 3 1.0 6 1.5 2.0 * * * * mV ppm ppm/ °C ppm/1000hrs µVpp OUTPUT CURRENT Range ±10 * * mA REGULATION Line Load 6 3 10 * * * * * * ppm/V ppm/mA OUTPUT ADJUSTMENT Range 10 POWER SUPPLY CURRENTS * mV (5) VRE302-6 +PS NOTES: * 5 7 *Same as A/J Models. 1. The temp. reference TC is 2.1mV/ °C 2. The specified values are without external trim. * * * * mA 4. The specified values are without the external noise reduction capacitor. 5. The specified values are unloaded. 3. The temperature coefficient is determined by the box method using the following formula: Vmax - Vmin x 106 T.C. = Vnominal x (Tmax-Tmin) VRE302-6DS REV. B MAY 2001 TYPICAL PERFORMANCE CURVES VOUT vs. TEMPERATURE Temperature oC VRE302-6A VOUT vs. TEMPERATURE Temperature oC VRE302-6J VOUT vs. TEMPERATURE Temperature oC VRE302-6B Temperature oC VRE302-6C VOUT vs. TEMPERATURE VOUT vs. TEMPERATURE Temperature oC VRE302-6K QUIESCENT CURRENT VS. TEMP JUNCTION TEMP. RISE VS. OUTPUT CURRENT Temperature oC VOUT vs. TEMPERATURE Output Current (mA) Temperature oC VRE302-6L PSRR VS. FREQUENCY Frequency (Hz) VRE302-6DS REV. B MAY 2001 DISCUSSION OF PERFORMANCE THEORY OF OPERATION The following discussion refers to the schematic in figure 2 below. A FET current source is used to bias a 6.3V zener diode. The zener voltage is divided by the resistor network R1 and R2. This voltage is then applied to the noninverting input of the operational amplifier which amplifies the voltage to produce a 2.048V output. The gain is determined by the resistor networks R3 and R4: G=1 + R4/R3. The 6.3V zener diode is used because it is the most stable diode over time and temperature. This network is less than 2% of the overall network resistance so it has a negligible effect on long term stability. Figure 3 shows the proper connection of the VRE302-6 series voltage references with the optional trim resistor for initial error. The VRE302-6 reference has the ground terminal brought out on two pins (pin 4 and pin 7) which are connected together internally. This allows the user to achieve greater accuracy when using a socket. Voltage references have a voltage drop across their power supply ground pin due to quiescent current flowing through the contact resistance. If the contact resistance was constant with time and temperature, this voltage drop could be trimmed out. When the reference is plugged into a socket, this source of error can be as high as 20ppm. By connecting pin 4 to the power supply ground and pin 7 to a high impedance ground point in the measurement circuit, the error due to the contact resistance can be eliminated. If the unit is soldered into place, the contact resistance is sufficiently small that it does not effect performance. Pay careful attention to the circuit layout to avoid noise pickup and voltage drops in the lines. The current source provides a closely regulated zener current, which determines the slope of the references’ voltage vs. temperature function. By trimming the zener current a lower drift over temperature can be achieved. But since the voltage vs. temperature function is nonlinear this compensation technique is not well suited for wide temperature ranges. Thaler Corporation has developed a nonlinear compensation network of thermistors and resistors that is used in the VRE series voltage references. This proprietary network eliminates most of the nonlinearity in the voltage vs. temperature function. By adjusting the slope, Thaler Corporation produces a very stable voltage over wide temperature ranges. VRE302-6 FIGURE 2 EXTERNAL CONNECTIONS + VIN 2 V TEMP OUT 3 8 OPTIONAL NOISE REDUCTION CAPACITOR 6 VRE302-6 CN 1µF 5 7 FIGURE 3 + VOUT 4 10kΩ OPTIONAL FINE TRIM ADJUSTMENT REF. GND VRE302-6DS REV. B MAY 2001 MECHANICAL FIGURE 3 D D1 INCHES D2 E1 E2 PIN 1 IDENTIFIER E MILLIMETER MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 D2 .018 .023 0.46 0.58 B .098 .102 2.48 2.59 E .507 .513 12.8 13.0 B1 .046 .051 1.14 1.29 E1 .397 .403 10.0 10.2 C .107 .113 2.71 2.89 E2 .264 .270 6.70 6.85 C1 .009 .012 0.22 0.30 P .085 .095 2.15 2.41 C2 .052 .058 1.32 1.47 Q .020 .030 .508 .762 S .045 .055 1.14 1.39 D .397 .403 10.0 10.2 D1 .372 .380 9.44 9.65 E1 P BASE SEATING B MILLIMETER MIN Q A INCHES DIM C1 C2 C S B1 FIGURE 4 INCHES MILLIMETER INCHES MILLIMETER DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 E .397 .403 10.0 10.2 B .018 .022 .457 .558 E1 .264 .270 6.70 6.85 B1 .046 .051 1.14 1.29 G1 .290 .310 7.36 7.87 B2 .098 .102 2.48 2.59 L .195 .215 4.95 5.46 C .009 .012 0.22 0.30 P .085 .095 2.15 2.41 D .397 .403 10.0 10.2 Q .055 .065 1.39 1.65 D1 .372 .380 9.44 9.65 S .045 .055 1.14 1.39 VRE302-6DS REV. B MAY 2001 VRE303 Low Cost Precision Reference THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 85745 • (520) 882-4000 FEATURES • 3.000 V OUTPUT ± 0.300 mV (.01%) PIN CONFIGURATION • TEMPERATURE DRIFT: 0.6 ppm/°C • LOW NOISE: 1.5µV p-p (0.1-10Hz) • INDUSTRY STD PINOUT- 8 PIN DIP OR SURFACE MOUNT PACKAGE N/C 1 +VIN 2 TEMP 3 GND 4 VRE303 TOP VIEW 8 NOISE REDUCTION 7 REF. GND 6 VOUT 5 TRIM •EXCELLENT LINE REGULATION: 6ppm/V Typ. • OUTPUT TRIM CAPABILITY FIGURE 1 DESCRIPTION The VRE303 is a low cost, high precision 3.0V reference. Packaged in the industry standard 8 pin DIP, the device is ideal for upgrading systems that use lower performance references. The device provides ultrastable +3.000V output with ±0.3000 mV (.01%) initial accuracy and a temperature coefficient of 0.6 ppm/°C. This improvement in accuracy is made possible by a unique, patented multipoint laser compensation technique developed by Thaler Corporation. Significant improvements have been made in other performance parameters as well, including initial accuracy, warm-up drift, line regulation, and long-term stability, making the VRE303 series the most accurate reference available in the standard 8 pin DIP package. For enhanced performance, the VRE303 has an external trim option for users who want less than 0.01% initial error. For ultra low noise applications, an external capacitor can be attached between the noise reduction pin and the ground pin. A reference ground pin is provided to eliminate socket contact resistance errors. The VRE303 is recommended for use as a reference for 14, 16, or 18 bit D/A converters which require an external precision reference. The device is also ideal for calibrating scale factor on high resolution A/D converters. The VRE303 offers superior performance over monolithic references. SELECTION GUIDE Model Initial Error mV Temp. Coeff. ppm/°C Temp. Range °C VRE303A VRE303B VRE303C VRE303J VRE303K VRE303L 0.30 0.48 0.60 0.30 0.48 0.60 0.6 1.0 2.0 0.6 1.0 2.0 0°C to +70°C 0°C to +70°C 0°C to +70°C -40°C to +85°C -40°C to +85°C -40°C to +85°C For package option add D for DIP or S for Surface Mount to end of model number. VRE303DS REV. B MAY 2001 ELECTRICAL SPECIFICATIONS VRE303 Vps =+15V, T = 25°C, RL = 10KΩ unless otherwise noted. MODEL A/J PARAMETER MIN TYP +14 0 -40 -65 +15 B/K MAX C/L MIN TYP MAX MIN TYP MAX UNITS * * * * * * * * * * * * * * * * * * V °C °C °C ABSOLUTE RATINGS Power Supply Operating Temp. (A,B,C) Operating Temp. (J,K,L) Storage Temperature Short Circuit Protection +16 +70 +85 +150 Continuous * * * * * * OUTPUT VOLTAGE VRE303 (1) Temp. Sensor Voltage 3.000 630 V mV OUTPUT VOLTAGE ERRORS (2) Initial Error Warmup Drift Tmin - Tmax (3) Long-Term Stability Noise (.1-10Hz) (4) 0.30 0.48 1 0.60 2 0.6 3 1.0 6 2.0 2.0 * * * * mV ppm ppm/°C ppm/1000hrs µVpp OUTPUT CURRENT Range ±10 * * mA REGULATION Line Load 6 3 10 * * * * * * ppm/V ppm/mA OUTPUT ADJUSTMENT Range 10 POWER SUPPLY CURRENTS * mV (5) VRE303 +PS NOTES: * 5 7 *Same as A/J Models. 1. The temp. reference TC is 2.1mV/ °C 2. The specified values are without external trim. * * * * mA 4. The specified values are without the external noise reduction capacitor. 5. The specified values are unloaded. 3. The temperature coefficient is determined by the box method using the following formula: Vmax - Vmin x 106 T.C. = Vnominal x (Tmax-Tmin) VRE303DS REV. B MAY 2001 TYPICAL PERFORMANCE CURVES VOUT vs. TEMPERATURE Temperature oC VRE303A VOUT vs. TEMPERATURE Temperature oC VRE303J QUIESCENT CURRENT VS. TEMP Temperature oC VOUT vs. TEMPERATURE VOUT vs. TEMPERATURE Temperature oC VRE303B Temperature oC VRE303C VOUT vs. TEMPERATURE Temperature oC VRE303K JUNCTION TEMP. RISE VS. OUTPUT CURRENT Output Current (mA) VOUT vs. TEMPERATURE Temperature oC VRE303L PSRR VS. FREQUENCY Frequency (Hz) VRE303DS REV. B MAY 2001 DISCUSSION OF PERFORMANCE THEORY OF OPERATION This network is less than 2% of the overall network resistance so it has a negligible effect on long term stability. The following discussion refers to the schematic in figure 2 below. A FET current source is used to bias a 6.3V zener diode. The zener voltage is divided by the resistor network R1 and R2. This voltage is then applied to the noninverting input of the operational amplifier which amplifies the voltage to produce a 3.000V output. The gain is determined by the resistor networks R3 and R4: G=1 + R4/R3. The 6.3V zener diode is used because it is the most stable diode over time and temperature. Figure 3 shows the proper connection of the VRE303 series voltage references with the optional trim resistor for initial error and the optional capacitor for noise reduction. The VRE303 reference has the ground terminal brought out on two pins (pin 4 and pin 7) which are connected together internally. This allows the user to achieve greater accuracy when using a socket. Voltage references have a voltage drop across their power supply ground pin due to quiescent current flowing through the contact resistance. If the contact resistance was constant with time and temperature, this voltage drop could be trimmed out. When the reference is plugged into a socket, this source of error can be as high as 20ppm. By connecting pin 4 to the power supply ground and pin 7 to a high impedance ground point in the measurement circuit, the error due to the contact resistance can be eliminated. If the unit is soldered into place, the contact resistance is sufficiently small that it does not effect performance. Pay careful attention to the circuit layout to avoid noise pickup and voltage drops in the lines. The current source provides a closely regulated zener current, which determines the slope of the references’ voltage vs. temperature function. By trimming the zener current a lower drift over temperature can be achieved. But since the voltage vs. temperature function is nonlinear this compensation technique is not well suited for wide temperature ranges. Thaler Corporation has developed a nonlinear compensation network of thermistors and resistors that is used in the VRE series voltage references. This proprietary network eliminates most of the nonlinearity in the voltage vs. temperature function. By adjusting the slope, Thaler Corporation produces a very stable voltage over wide temperature ranges. VRE303 FIGURE 2 EXTERNAL CONNECTIONS + VIN V TEMP OUT 2 3 8 OPTIONAL NOISE REDUCTION CAPACITOR 6 VRE303 CN 1µF 5 7 FIGURE 3 + VOUT 4 10kΩ OPTIONAL FINE TRIM ADJUSTMENT REF. GND VRE303DS REV. B MAY 2001 MECHANICAL FIGURE 3 D D1 INCHES D2 E1 E2 PIN 1 IDENTIFIER E MILLIMETER MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 D2 .018 .023 0.46 0.58 B .098 .102 2.48 2.59 E .507 .513 12.8 13.0 B1 .046 .051 1.14 1.29 E1 .397 .403 10.0 10.2 C .107 .113 2.71 2.89 E2 .264 .270 6.70 6.85 C1 .009 .012 0.22 0.30 P .085 .095 2.15 2.41 C2 .052 .058 1.32 1.47 Q .020 .030 .508 .762 D .397 .403 10.0 10.2 S .045 .055 1.14 1.39 D1 .372 .380 9.44 9.65 E1 P BASE SEATING B MILLIMETER MIN Q A INCHES DIM C1 C2 C S B1 FIGURE 4 INCHES MILLIMETER INCHES MILLIMETER DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 E .397 .403 10.0 10.2 B .018 .022 .457 .558 E1 .264 .270 6.70 6.85 B1 .046 .051 1.14 1.29 G1 .290 .310 7.36 7.87 B2 .098 .102 2.48 2.59 L .195 .215 4.95 5.46 C .009 .012 0.22 0.30 P .085 .095 2.15 2.41 D .397 .403 10.0 10.2 Q .055 .065 1.39 1.65 D1 .372 .380 9.44 9.65 S .045 .055 1.14 1.39 VRE303DS REV. B MAY 2001 VRE304 Low Cost Precision Reference THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 85745 • (520) 882-4000 FEATURES • 4.500 V OUTPUT ± 0.450 mV (.01%) PIN CONFIGURATION • TEMPERATURE DRIFT: 0.6 ppm/°C • LOW NOISE: 3µV p-p (0.1-10Hz) • INDUSTRY STD PINOUT- 8 PIN DIP OR SURFACE MOUNT PACKAGE N/C 1 +VIN 2 TEMP 3 GND 4 VRE304 TOP VIEW 8 NOISE REDUCTION 7 REF. GND 6 VOUT 5 TRIM •EXCELLENT LINE REGULATION: 6ppm/V Typ. • OUTPUT TRIM CAPABILITY FIGURE 1 DESCRIPTION The VRE304 is a low cost, high precision 4.5V reference. Packaged in the industry standard 8 pin DIP, the device is ideal for upgrading systems that use lower performance references. The device provides ultrastable +4.500V output with ±0.4500 mV (.01%) initial accuracy and a temperature coefficient of 0.6 ppm/°C. This improvement in accuracy is made possible by a unique, patented multipoint laser compensation technique developed by Thaler Corporation. Significant improvements have been made in other performance parameters as well, including initial accuracy, warm-up drift, line regulation, and long-term stability, making the VRE304 series the most accurate reference available in the standard 8 pin DIP package. For enhanced performance, the VRE304 has an external trim option for users who want less than 0.01% initial error. For ultra low noise applications, an external capacitor can be attached between the noise reduction pin and the ground pin. A reference ground pin is provided to eliminate socket contact resistance errors. The VRE304 is recommended for use as a reference for 14, 16, or 18 bit D/A converters which require an external precision reference. The device is also ideal for calibrating scale factor on high resolution A/D converters. The VRE304 offers superior performance over monolithic references. SELECTION GUIDE Model Initial Error mV Temp. Coeff. ppm/°C Temp. Range °C VRE304A VRE304B VRE304C VRE304J VRE304K VRE304L 0.45 0.70 0.90 0.45 0.70 0.90 0.6 1.0 2.0 0.6 1.0 2.0 0°C to +70°C 0°C to +70°C 0°C to +70°C -40°C to +85°C -40°C to +85°C -40°C to +85°C For package option add D for DIP or S for Surface Mount to end of model number. VRE304DS REV. D MAY 2001 ELECTRICAL SPECIFICATIONS VRE304 Vps =+15V, T = 25°C, RL = 10KΩ unless otherwise noted. MODEL A/J PARAMETER MIN TYP +13.5 0 -40 -65 +15 B/K MAX C/L MIN TYP MAX MIN TYP MAX UNITS * * * * * * * * * * * * * * * * * * V °C °C °C ABSOLUTE RATINGS Power Supply Operating Temp. (A,B,C) Operating Temp. (J,K,L) Storage Temperature Short Circuit Protection +22 +70 +85 +150 Continuous * * * * * * OUTPUT VOLTAGE VRE304 (1) Temp. Sensor Voltage 4.500 630 V mV OUTPUT VOLTAGE ERRORS (2) Initial Error Warmup Drift Tmin - Tmax (3) Long-Term Stability Noise (.1-10Hz) (4) 0.45 0.70 1 0.90 2 0.6 3 1.0 6 3 2.0 * * * * mV ppm ppm/°C ppm/1000hrs µVpp OUTPUT CURRENT Range ±10 * * mA REGULATION Line Load 6 3 10 * * * * * * ppm/V ppm/mA OUTPUT ADJUSTMENT Range 10 POWER SUPPLY CURRENTS * mV (5) VRE304 +PS NOTES: * 5 7 *Same as A/J Models. 1. The temp. reference TC is 2.1mV/ °C 2. The specified values are without external trim. * * * * mA 4. The specified values are without the external noise reduction capacitor. 5. The specified values are unloaded. 3. The temperature coefficient is determined by the box method using the following formula: Vmax - Vmin x 106 T.C. = Vnominal x (Tmax-Tmin) VRE304DS REV. D MAY 2001 TYPICAL PERFORMANCE CURVES VOUT vs. TEMPERATURE Temperature oC VRE304A VOUT vs. TEMPERATURE Temperature oC VRE304J QUIESCENT CURRENT VS. TEMP Temperature oC VOUT vs. TEMPERATURE Temperature oC VRE304B VOUT vs. TEMPERATURE Temperature oC VRE304K JUNCTION TEMP. RISE VS. OUTPUT CURRENT Output Current (mA) VOUT vs. TEMPERATURE Temperature oC VRE304C VOUT vs. TEMPERATURE Temperature oC VRE304L PSRR VS. FREQUENCY Frequency (Hz) VRE304DS REV. D MAY 2001 DISCUSSION OF PERFORMANCE THEORY OF OPERATION The following discussion refers to the schematic in figure 2 below. A FET current source is used to bias a 6.3V zener diode. The zener voltage is divided by the resistor network R1 and R2. This voltage is then applied to the noninverting input of the operational amplifier which amplifies the voltage to produce a 4.500V output. The gain is determined by the resistor networks R3 and R4: G=1 + R4/R3. The 6.3V zener diode is used because it is the most stable diode over time and temperature. This network is less than 2% of the overall network resistance so it has a negligible effect on long term stability. Figure 3 shows the proper connection of the VRE304 series voltage references with the optional trim resistor for initial error and the optional capacitor for noise reduction. The VRE304 reference has the ground terminal brought out on two pins (pin 4 and pin 7) which are connected together internally. This allows the user to achieve greater accuracy when using a socket. Voltage references have a voltage drop across their power supply ground pin due to quiescent current flowing through the contact resistance. If the contact resistance was constant with time and temperature, this voltage drop could be trimmed out. When the reference is plugged into a socket, this source of error can be as high as 20ppm. By connecting pin 4 to the power supply ground and pin 7 to a high impedance ground point in the measurement circuit, the error due to the contact resistance can be eliminated. If the unit is soldered into place, the contact resistance is sufficiently small that it does not effect performance. Pay careful attention to the circuit layout to avoid noise pickup and voltage drops in the lines. The current source provides a closely regulated zener current, which determines the slope of the references’ voltage vs. temperature function. By trimming the zener current a lower drift over temperature can be achieved. But since the voltage vs. temperature function is nonlinear this compensation technique is not well suited for wide temperature ranges. Thaler Corporation has developed a nonlinear compensation network of thermistors and resistors that is used in the VRE series voltage references. This proprietary network eliminates most of the nonlinearity in the voltage vs. temperature function. By adjusting the slope, Thaler Corporation produces a very stable voltage over wide temperature ranges. VRE304 FIGURE 2 EXTERNAL CONNECTIONS + VIN V TEMP OUT 2 3 8 OPTIONAL NOISE REDUCTION CAPACITOR 6 VRE304 CΝ 1µF 5 7 FIGURE 3 + VOUT 4 10kΩ OPTIONAL FINE TRIM ADJUSTMENT REF. GND VRE304DS REV. D MAY 2001 MECHANICAL FIGURE 3 D D1 INCHES D2 E1 E2 PIN 1 IDENTIFIER E MILLIMETER MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 D2 .018 .023 0.46 0.58 B .098 .102 2.48 2.59 E .507 .513 12.8 13.0 B1 .046 .051 1.14 1.29 E1 .397 .403 10.0 10.2 C .107 .113 2.71 2.89 E2 .264 .270 6.70 6.85 C1 .009 .012 0.22 0.30 P .085 .095 2.15 2.41 C2 .052 .058 1.32 1.47 Q .020 .030 .508 .762 S .045 .055 1.14 1.39 D .397 .403 10.0 10.2 D1 .372 .380 9.44 9.65 E1 P BASE SEATING B MILLIMETER MIN Q A INCHES DIM C1 C2 C S B1 FIGURE 4 INCHES MILLIMETER INCHES MILLIMETER DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 E .397 .403 10.0 10.2 B .018 .022 .457 .558 E1 .264 .270 6.70 6.85 B1 .046 .051 1.14 1.29 G1 .290 .310 7.36 7.87 B2 .098 .102 2.48 2.59 L .195 .215 4.95 5.46 C .009 .012 0.22 0.30 P .085 .095 2.15 2.41 D .397 .403 10.0 10.2 Q .055 .065 1.39 1.65 D1 .372 .380 9.44 9.65 S .045 .055 1.14 1.39 VRE304DS REV. D MAY 2001 VRE304-6 Low Cost Precision Reference THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 8574 5 • (520) 882 -4000 FEATURES • 4.096 V OUTPUT ± 0.409 mV (.01%) PIN CONFIGURATION • TEMPERATURE DRIFT: 0.6 ppm/°C • LOW NOISE: 3µV p-p (0.1-10Hz) • INDUSTRY STD PINOUT- 8 PIN DIP OR SURFACE MOUNT PACKAGE N/C 1 +VIN 2 TEMP 3 GND 4 VRE304-6 TOP VIEW 8 NOISE REDUCTION 7 REF. GND 6 VOUT 5 TRIM •EXCELLENT LINE REGULATION: 6ppm/V Typ. • OPERATES ON +15V SUPPLY FIGURE 1 DESCRIPTION The VRE304-6 is a low cost, high precision 4.096V reference. Packaged in the industry standard 8 pin DIP, the device is ideal for upgrading systems that use lower performance references. The device provides ultrastable +4.096V output with ±0.409 mV (.01%) initial accuracy and a temperature coefficient of 0.6 ppm/°C. This improvement in accuracy is made possible by a unique, patented multipoint laser compensation technique developed by Thaler Corporation. Significant improvements have been made in other performance parameters as well, including initial accuracy, warm-up drift, line regulation, and long-term stability, making the VRE304-6 series the most accurate reference available in the standard 8 pin DIP package. For enhanced performance, the VRE304-6 has an external trim option for users who want less than 0.01% initial error. For ultra low noise applications, an external capacitor can be attached between the noise reduction pin and the ground pin. A reference ground pin is provided to eliminate socket contact resistance errors. The VRE304-6 is recommended for use as a reference for 14, 16, or 18 bit D/A converters which require an external precision reference. The device is also ideal for calibrating scale factor on high resolution A/D converters. The VRE3046 offers superior performance over monolithic references. SELECTION GUIDE Model Initial Error mV Temp. Coeff. ppm/°C Temp. Range °C VRE304-6A VRE304-6B VRE304-6C VRE304-6J VRE304-6K VRE304-6L 0.41 0.64 0.82 0.41 0.64 0.82 0.6 1.0 2.0 0.6 1.0 2.0 0°C to +70°C 0°C to +70°C 0°C to +70°C -40°C to +85°C -40°C to +85°C -40°C to +85°C For package option add D for DIP or S for Surface Mount to end of model number. VRE304-6DS REV. D JUN 1999 ELECTRICAL SPECIFICATIONS VRE304-6 Vps =+15V, T = 25°C, RL = 10KΩ unless otherwise noted. MODEL A/J PARAMETER MIN TYP +13 0 -40 -65 +15 B/K MAX C/L MIN TYP MAX MIN TYP MAX UNITS * * * * * * * * * * * * * * * * * * V °C °C °C ABSOLUTE RATINGS Power Supply Operating Temp. (A,B,C) Operating Temp. (J,K,L) Storage Temperature Short Circuit Protection +22 +70 +85 +150 Continuous * * * * * * OUTPUT VOLTAGE VRE304-6 (1) Temp. Sensor Voltage 4.096 630 V mV OUTPUT VOLTAGE ERRORS (2) Initial Error Warmup Drift Tmin - Tmax (3) Long-Term Stability Noise (.1-10Hz) (4) 0.41 0.64 1 0.82 2 0.6 3 1.0 6 3 2.0 * * * * mV ppm ppm/ °C ppm/1000hrs µVpp OUTPUT CURRENT Range ±10 * * mA REGULATION Line Load 6 3 10 * * * * * * ppm/V ppm/mA OUTPUT ADJUSTMENT Range 10 POWER SUPPLY CURRENTS * mV (5) VRE304-6 +PS NOTES: * 5 7 *Same as A/J Models. 1. The temp. reference TC is 2.1mV/ °C 2. The specified values are without external trim. * * * * mA 4. The specified values are without the external noise reduction capacitor. 5. The specified values are unloaded. 3. The temperature coefficient is determined by the box method using the following formula: Vmax - Vmin x 106 T.C. = Vnominal x (Tmax-Tmin) VRE304-6DS REV. D JUN 1999 TYPICAL PERFORMANCE CURVES VOUT vs. TEMPERATURE Temperature oC VRE304-6A VOUT vs. TEMPERATURE Temperature oC VRE304-6J QUIESCENT CURRENT VS. TEMP Temperature oC VOUT vs. TEMPERATURE Temperature oC VRE304-6B VOUT vs. TEMPERATURE Temperature oC VRE304-6K JUNCTION TEMP. RISE VS. OUTPUT CURRENT Output Current (mA) VOUT vs. TEMPERATURE Temperature oC VRE304-6C VOUT vs. TEMPERATURE Temperature oC VRE304-6L PSRR VS. FREQUENCY Frequency (Hz) VRE304-6DS REV. D JUN 1999 DISCUSSION OF PERFORMANCE THEORY OF OPERATION The following discussion refers to the schematic in figure 2 below. A FET current source is used to bias a 6.3V zener diode. The zener voltage is divided by the resistor network R1 and R2. This voltage is then applied to the noninverting input of the operational amplifier which amplifies the voltage to produce a 4.096V output. The gain is determined by the resistor networks R3 and R4: G=1 + R4/R3. The 6.3V zener diode is used because it is the most stable diode over time and temperature. This network is less than 2% of the overall network resistance so it has a negligible effect on long term stability. Figure 3 shows the proper connection of the VRE304-6 series voltage references with the optional trim resistor for initial error and the optional capacitor for noise reduction. The VRE304-6 reference has the ground terminal brought out on two pins (pin 4 and pin 7) which are connected together internally. This allows the user to achieve greater accuracy when using a socket. Voltage references have a voltage drop across their power supply ground pin due to quiescent current flowing through the contact resistance. If the contact resistance was constant with time and temperature, this voltage drop could be trimmed out. When the reference is plugged into a socket, this source of error can be as high as 20ppm. By connecting pin 4 to the power supply ground and pin 7 to a high impedance ground point in the measurement circuit, the error due to the contact resistance can be eliminated. If the unit is soldered into place, the contact resistance is sufficiently small that it does not effect performance. Pay careful attention to the circuit layout to avoid noise pickup and voltage drops in the lines. The current source provides a closely regulated zener current, which determines the slope of the references’ voltage vs. temperature function. By trimming the zener current a lower drift over temperature can be achieved. But since the voltage vs. temperature function is nonlinear this compensation technique is not well suited for wide temperature ranges. Thaler Corporation has developed a nonlinear compensation network of thermistors and resistors that is used in the VRE series voltage references. This proprietary network eliminates most of the nonlinearity in the voltage vs. temperature function. By adjusting the slope, Thaler Corporation produces a very stable voltage over wide temperature ranges. VRE304-6 FIGURE 2 EXTERNAL CONNECTIONS + VIN 2 V TEMP OUT 3 8 OPTIONAL NOISE REDUCTION CAPACITOR 6 VRE304-6 CN 1µF 5 7 FIGURE 3 + VOUT 4 10k? OPTIONAL FINE TRIM ADJUSTMENT REF. GND VRE304-6DS REV. D JUN 1999 MECHANICAL SPECIFICATIONS FIGURE 3 INCHES MILLIMETER MAX INCHES MILLIMETER DIM MIN MAX MIN DIM MIN MAX MIN A .110 .120 2.794 3.048 D1 .372 .380 9.45 MAX B .095 .105 2.413 2.667 E .425 .435 10.80 11.05 B1 .021 .027 0.533 0.686 E1 .397 .403 10.08 10.24 C .055 .065 1.397 1.651 E2 .264 .270 6.71 6.86 C1 .012 .020 0.305 0.508 P .085 .095 2.16 2.41 C2 .020 .040 0.508 1.016 S .045 .055 1.14 1.40 D .395 .405 10.03 10.29 9.65 D D1 E2 E1 E 1 A P C1 B S B1 C C2 VRE304-6DS REV. D JUN 1999 MECHANICAL SPECIFICATIONS INCHES MILLIMETER MILLIMETER DIM MIN MAX MIN DIM MIN MAX MIN A .170 .180 4.318 4.572 E .425 .435 10.80 11.05 B .095 .105 2.413 2.667 E1 .397 .403 10.08 10.24 B1 .016 .020 0.406 0.508 E2 .264 .270 6.71 6.86 C .008 .011 0.203 0.279 G .290 .310 7.36 7.87 C1 .055 .065 1.397 1.651 L .175 .225 4.46 5.72 D .395 .405 10.03 10.29 P .085 .095 2.16 2.41 D1 .372 .380 S .045 .055 1.14 1.40 9.45 MAX INCHES 9.65 MAX D D1 E2 E1 E 1 P A C1 L C S B G B1 VRE304-4DS REV. D JUN 1999 VRE305 Low Cost Precision Reference THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 85745 • (520) 882-4000 FEATURES • 5.000 V OUTPUT ± 0.500 mV (.01%) PIN CONFIGURATION • TEMPERATURE DRIFT: 0.6 ppm/°C • LOW NOISE: 3µV p-p (0.1-10Hz) • INDUSTRY STD PINOUT- 8 PIN DIP OR SURFACE MOUNT PACKAGE N/C 1 +VIN 2 TEMP 3 GND 4 VRE305 TOP VIEW 8 NOISE REDUCTION 7 REF. GND 6 VOUT 5 TRIM •EXCELLENT LINE REGULATION: 6ppm/V Typ. • OUTPUT TRIM CAPABILITY FIGURE 1 DESCRIPTION The VRE305 is a low cost, high precision 5.0V reference. Packaged in the industry standard 8 pin DIP, the device is ideal for upgrading systems that use lower performance references. The device provides ultrastable +5.000V output with ±0.5000 mV (.01%) initial accuracy and a temperature coefficient of 0.6 ppm/°C. This improvement in accuracy is made possible by a unique, patented multipoint laser compensation technique developed by Thaler Corporation. Significant improvements have been made in other performance parameters as well, including initial accuracy, warm-up drift, line regulation, and long-term stability, making the VRE305 series the most accurate reference available in the standard 8 pin DIP package. For enhanced performance, the VRE305 has an external trim option for users who want less than 0.01% initial error. For ultra low noise applications, an external capacitor can be attached between the noise reduction pin and the ground pin. A reference ground pin is provided to eliminate socket contact resistance errors. The VRE305 is recommended for use as a reference for 14, 16, or 18 bit D/A converters which require an external precision reference. The device is also ideal for calibrating scale factor on high resolution A/D converters. The VRE305 offers superior performance over monolithic references. SELECTION GUIDE Model Initial Error mV VRE305A VRE305B VRE305C VRE305J VRE305K VRE305L 0.5 0.8 1.0 0.5 0.8 1.0 Temp. Coeff. ppm/°C 0.6 1.0 2.0 0.6 1.0 2.0 Temp. Range °C 0°C to +70°C 0°C to +70°C 0°C to +70°C -40°C to +85°C -40°C to +85°C -40°C to +85°C For package option add D for DIP or S for Surface Mount to end of model number. VRE305DS REV. D MAY 2001 ELECTRICAL SPECIFICATIONS VRE305 Vps =+15V, T = 25°C, RL = 10kΩ unless otherwise noted. MODEL A/J PARAMETER MIN TYP +13.5 0 -40 -65 +15 B/K MAX C/L MIN TYP MAX MIN TYP MAX UNITS * * * * * * * * * * * * * * * * * * V °C °C °C ABSOLUTE RATINGS Power Supply Operating Temp. (A,B,C) Operating Temp. (J,K,L) Storage Temperature Short Circuit Protection +22 +70 +85 +150 Continuous * * * * * * OUTPUT VOLTAGE VRE305 (1) Temp. Sensor Voltage 5.000 630 V mV OUTPUT VOLTAGE ERRORS (2) Initial Error Warmup Drift Tmin - Tmax (3) Long-Term Stability Noise (.1-10Hz) (4) 0.50 0.80 1 1.00 2 0.6 3 1.0 6 3 2.0 * * * * mV ppm ppm/°C ppm/1000hrs µVpp OUTPUT CURRENT Range ±10 * * mA REGULATION Line Load 6 3 10 * * * * * * ppm/V ppm/mA OUTPUT ADJUSTMENT Range 10 POWER SUPPLY CURRENTS * mV (5) VRE305 +PS NOTES: * 5 7 *Same as A/J Models. 1. The temp. reference TC is 2.1mV/°C 2. The specified values are without external trim. * * * * mA 4. The specified values are without the external noise reduction capacitor. 5. The specified values are unloaded. 3. The temperature coefficient is determined by the box method using the following formula: Vmax - Vmin x 106 T.C. = Vnominal x (Tmax-Tmin) VRE305DS REV. D MAY 2001 TYPICAL PERFORMANCE CURVES VOUT vs. TEMPERATURE Temperature oC VRE305A VOUT vs. TEMPERATURE Temperature oC VRE305J QUIESCENT CURRENT VS. TEMP Temperature oC VOUT vs. TEMPERATURE Temperature oC VRE305B VOUT vs. TEMPERATURE Temperature oC VRE305K JUNCTION TEMP. RISE VS. OUTPUT CURRENT Output Current (mA) VOUT vs. TEMPERATURE Temperature oC VRE305C VOUT vs. TEMPERATURE Temperature oC VRE305L PSRR VS. FREQUENCY Frequency (Hz) VRE305DS REV. D MAY 2001 DISCUSSION OF PERFORMANCE THEORY OF OPERATION The following discussion refers to the schematic in figure 2 below. A FET current source is used to bias a 6.3V zener diode. The zener voltage is divided by the resistor network R1 and R2. This voltage is then applied to the noninverting input of the operational amplifier which amplifies the voltage to produce a 5.000V output. The gain is determined by the resistor networks R3 and R4: G=1 + R4/R3. The 6.3V zener diode is used because it is the most stable diode over time and temperature. This network is less than 2% of the overall network resistance so it has a negligible effect on long term stability. Figure 3 shows the proper connection of the VRE305 series voltage references with the optional trim resistor for initial error and the optional capacitor for noise reduction. The VRE305 reference has the ground terminal brought out on two pins (pin 4 and pin 7) which are connected together internally. This allows the user to achieve greater accuracy when using a socket. Voltage references have a voltage drop across their power supply ground pin due to quiescent current flowing through the contact resistance. If the contact resistance was constant with time and temperature, this voltage drop could be trimmed out. When the reference is plugged into a socket, this source of error can be as high as 20ppm. By connecting pin 4 to the power supply ground and pin 7 to a high impedance ground point in the measurement circuit, the error due to the contact resistance can be eliminated. If the unit is soldered into place, the contact resistance is sufficiently small that it does not effect performance. Pay careful attention to the circuit layout to avoid noise pickup and voltage drops in the lines. The current source provides a closely regulated zener current, which determines the slope of the references’ voltage vs. temperature function. By trimming the zener current a lower drift over temperature can be achieved. But since the voltage vs. temperature function is nonlinear this compensation technique is not well suited for wide temperature ranges. Thaler Corporation has developed a nonlinear compensation network of thermistors and resistors that is used in the VRE series voltage references. This proprietary network eliminates most of the nonlinearity in the voltage vs. temperature function. By adjusting the slope, Thaler Corporation produces a very stable voltage over wide temperature ranges. VRE305 FIGURE 2 EXTERNAL CONNECTIONS + VIN V TEMP OUT 2 3 8 OPTIONAL NOISE REDUCTION CAPACITOR 6 VRE305 CN 1µF 5 7 FIGURE 3 + VOUT 4 10KΩ OPTIONAL FINE TRIM ADJUSTMENT REF. GND VRE305DS REV. D MAY 2001 MECHANICAL FIGURE 3 D D1 INCHES D2 E1 E2 E PIN 1 IDENTIFIER MILLIMETER MILLIMETER MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 D2 .018 .023 0.46 0.58 B .098 .102 2.48 2.59 E .507 .513 12.8 13.0 B1 .046 .051 1.14 1.29 E1 .397 .403 10.0 10.2 C .107 .113 2.71 2.89 E2 .264 .270 6.70 6.85 C1 .009 .012 0.22 0.30 P .085 .095 2.15 2.41 C2 .052 .058 1.32 1.47 Q .020 .030 .508 .762 S .045 .055 1.14 1.39 D .397 .403 10.0 10.2 D1 .372 .380 9.44 9.65 E1 Q A INCHES DIM P BASE SEATING C1 C2 B S C B1 FIGURE 4 INCHES MILLIMETER INCHES MILLIMETER DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 E .397 .403 10.0 10.2 B .018 .022 .457 .558 E1 .264 .270 6.70 6.85 B1 .046 .051 1.14 1.29 G1 .290 .310 7.36 7.87 B2 .098 .102 2.48 2.59 L .195 .215 4.95 5.46 C .009 .012 0.22 0.30 P .085 .095 2.15 2.41 D .397 .403 10.0 10.2 Q .055 .065 1.39 1.65 D1 .372 .380 9.44 9.65 S .045 .055 1.14 1.39 VRE305DS REV. D MAY 2001 VRE306 Low Cost Precision Reference THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 85745 • (520) 882-4000 FEATURES • 6.000 V OUTPUT ± 0.600 mV (.01%) PIN CONFIGURATION • TEMPERATURE DRIFT: 0.6 ppm/°C • LOW NOISE: 4µV p-p (0.1-10Hz) • INDUSTRY STD PINOUT- 8 PIN DIP OR SURFACE MOUNT PACKAGE N/C 1 +VIN 2 TEMP 3 GND 4 VRE306 TOP VIEW 8 NOISE REDUCTION 7 REF. GND 6 VOUT 5 TRIM •EXCELLENT LINE REGULATION: 6ppm/V Typ. • OUTPUT TRIM CAPABILITY FIGURE 1 DESCRIPTION The VRE306 is a low cost, high precision 6.0V reference. Packaged in the industry standard 8 pin DIP, the device is ideal for upgrading systems that use lower performance references. The device provides ultrastable +6.000V output with ±0.6000 mV (.01%) initial accuracy and a temperature coefficient of 0.6 ppm/°C. This improvement in accuracy is made possible by a unique, patented multipoint laser compensation technique developed by Thaler Corporation. Significant improvements have been made in other performance parameters as well, including initial accuracy, warm-up drift, line regulation, and long-term stability, making the VRE306 series the most accurate reference available in the standard 8 pin DIP package. For enhanced performance, the VRE306 has an external trim option for users who want less than 0.01% initial error. For ultra low noise applications, an external capacitor can be attached between the noise reduction pin and the ground pin. A reference ground pin is provided to eliminate socket contact resistance errors. The VRE306 is recommended for use as a reference for 14, 16, or 18 bit D/A converters which require an external precision reference. The device is also ideal for calibrating scale factor on high resolution A/D converters. The VRE306 offers superior performance over monolithic references. SELECTION GUIDE Model Initial Error mV VRE306A VRE306C VRE306J VRE306K VRE306L 0.6 1.2 0.6 1.0 1.2 Temp. Coeff. ppm/°C 0.6 2.0 0.6 1.0 2.0 Temp. Range °C 0°C to +70°C 0°C to +70°C -40°C to +85°C -40°C to +85°C -40°C to +85°C For package option add D for DIP or S for Surface Mount to end of model number. VRE306DS REV. B MAY 2001 ELECTRICAL SPECIFICATIONS VRE306 Vps =+15V, T = 25°C, RL = 10KΩ unless otherwise noted. MODEL A/J PARAMETER MIN TYP +14 0 -40 -65 +15 B/K MAX C/L MIN TYP MAX MIN TYP MAX UNITS * * * * * * * * * * * * * * * * * * V °C °C °C ABSOLUTE RATINGS Power Supply Operating Temp. (A,B,C) Operating Temp. (J,K,L) Storage Temperature Short Circuit Protection +16 +70 +85 +150 Continuous * * * * * * OUTPUT VOLTAGE VRE306 (1) Temp. Sensor Voltage 6.000 630 V mV OUTPUT VOLTAGE ERRORS (2) Initial Error Warmup Drift Tmin - Tmax (3) Long-Term Stability Noise (.1-10Hz) (4) 0.60 1.00 1 1.20 2 0.6 3 1.0 6 4 2.0 * * * * mV ppm ppm/ °C ppm/1000hrs µVpp OUTPUT CURRENT Range ±10 * * mA REGULATION Line Load 6 3 10 * * * * * * ppm/V ppm/mA OUTPUT ADJUSTMENT Range 10 POWER SUPPLY CURRENTS * mV (5) VRE306 +PS NOTES: * 5 7 *Same as A/J Models. 1. The temp. reference TC is 2.1mV/ °C 2. The specified values are without external trim. * * * * mA 4. The specified values are without the external noise reduction capacitor. 5. The specified values are unloaded. 3. The temperature coefficient is determined by the box method using the following formula: Vmax - Vmin x 106 T.C. = Vnominal x (Tmax-Tmin) VRE306DS REV. B MAY 2001 TYPICAL PERFORMANCE CURVES VOUT vs. TEMPERATURE Temperature oC VRE306A VOUT vs. TEMPERATURE Temperature oC VRE306J QUIESCENT CURRENT VS. TEMP Temperature oC VOUT vs. TEMPERATURE Temperature oC VRE306B VOUT vs. TEMPERATURE Temperature oC VRE306K JUNCTION TEMP. RISE VS. OUTPUT CURRENT Output Current (mA) VOUT vs. TEMPERATURE Temperature oC VRE306C VOUT vs. TEMPERATURE Temperature oC VRE306L PSRR VS. FREQUENCY Frequency (Hz) VRE306DS REV. B MAY 2001 DISCUSSION OF PERFORMANCE THEORY OF OPERATION The following discussion refers to the schematic in figure 2 below. A FET current source is used to bias a 6.3V zener diode. The zener voltage is divided by the resistor network R1 and R2. This voltage is then applied to the noninverting input of the operational amplifier which amplifies the voltage to produce a 6.000V output. The gain is determined by the resistor networks R3 and R4: G=1 + R4/R3. The 6.3V zener diode is used because it is the most stable diode over time and temperature. This network is less than 2% of the overall network resistance so it has a negligible effect on long term stability. Figure 3 shows the proper connection of the VRE306 series voltage references with the optional trim resistor for initial error and the optional capacitor for noise reduction. The VRE306 reference has the ground terminal brought out on two pins (pin 4 and pin 7) which are connected together internally. This allows the user to achieve greater accuracy when using a socket. Voltage references have a voltage drop across their power supply ground pin due to quiescent current flowing through the contact resistance. If the contact resistance was constant with time and temperature, this voltage drop could be trimmed out. When the reference is plugged into a socket, this source of error can be as high as 20ppm. By connecting pin 4 to the power supply ground and pin 7 to a high impedance ground point in the measurement circuit, the error due to the contact resistance can be eliminated. If the unit is soldered into place, the contact resistance is sufficiently small that it does not effect performance. Pay careful attention to the circuit layout to avoid noise pickup and voltage drops in the lines. The current source provides a closely regulated zener current, which determines the slope of the references’ voltage vs. temperature function. By trimming the zener current a lower drift over temperature can be achieved. But since the voltage vs. temperature function is nonlinear this compensation technique is not well suited for wide temperature ranges. Thaler Corporation has developed a nonlinear compensation network of thermistors and resistors that is used in the VRE series voltage references. This proprietary network eliminates most of the nonlinearity in the voltage vs. temperature function. By adjusting the slope, Thaler Corporation produces a very stable voltage over wide temperature ranges. VRE306 FIGURE 2 EXTERNAL CONNECTIONS + VIN V TEMP OUT 2 3 8 OPTIONAL NOISE REDUCTION CAPACITOR 6 VRE306 CN 1µF 5 7 FIGURE 3 + VOUT 4 10kW OPTIONAL FINE TRIM ADJUSTMENT REF. GND VRE306DS REV. B MAY 2001 MECHANICAL FIGURE 3 D D1 INCHES D2 E1 E2 E PIN 1 IDENTIFIER MILLIMETER MILLIMETER MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 D2 .018 .023 0.46 0.58 B .098 .102 2.48 2.59 E .507 .513 12.8 13.0 B1 .046 .051 1.14 1.29 E1 .397 .403 10.0 10.2 C .107 .113 2.71 2.89 E2 .264 .270 6.70 6.85 C1 .009 .012 0.22 0.30 P .085 .095 2.15 2.41 C2 .052 .058 1.32 1.47 Q .020 .030 .508 .762 S .045 .055 1.14 1.39 D .397 .403 10.0 10.2 D1 .372 .380 9.44 9.65 E1 Q A INCHES DIM P BASE SEATING C1 C2 B S C B1 FIGURE 4 INCHES MILLIMETER INCHES MILLIMETER DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 E .397 .403 10.0 10.2 B .018 .022 .457 .558 E1 .264 .270 6.70 6.85 B1 .046 .051 1.14 1.29 G1 .290 .310 7.36 7.87 B2 .098 .102 2.48 2.59 L .195 .215 4.95 5.46 C .009 .012 0.22 0.30 P .085 .095 2.15 2.41 D .397 .403 10.0 10.2 Q .055 .065 1.39 1.65 D1 .372 .380 9.44 9.65 S .045 .055 1.14 1.39 VRE306DS REV. B MAY 2001 VRE310 Low Cost Precision Reference THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 85745 • (520) 882-4000 FEATURES • 10.000 V OUTPUT ± 1.000 mV (.01%) PIN CONFIGURATION • TEMPERATURE DRIFT: 0.6 ppm/°C • LOW NOISE: 6µV p-p (0.1-10Hz) • INDUSTRY STD PINOUT- 8 PIN DIP OR SURFACE MOUNT PACKAGE N/C 1 +VIN 2 TEMP 3 GND 4 VRE310 TOP VIEW 8 NOISE REDUCTION 7 REF. GND 6 VOUT 5 TRIM •EXCELLENT LINE REGULATION: 6ppm/V Typ. • OUTPUT TRIM CAPABILITY FIGURE 1 DESCRIPTION The VRE310 is a low cost, high precision 10.0V reference. Packaged in the industry standard 8 pin DIP, the device is ideal for upgrading systems that use lower performance references. The device provides ultrastable +10.000V output with ±1.000 mV (.01%) initial accuracy and a temperature coefficient of 0.6 ppm/°C. This improvement in accuracy is made possible by a unique, patented multipoint laser compensation technique developed by Thaler Corporation. Significant improvements have been made in other performance parameters as well, including initial accuracy, warm-up drift, line regulation, and long-term stability, making the VRE310 series the most accurate reference available in the standard 8 pin DIP package. For enhanced performance, the VRE310 has an external trim option for users who want less than 0.01% initial error. For ultra low noise applications, an external capacitor can be attached between the noise reduction pin and the ground pin. A reference ground pin is provided to eliminate socket contact resistance errors. The VRE310 is recommended for use as a reference for 14-, 16-, or 18-bit D/A converters which require an external precision reference. The device is also ideal for calibrating scale factor on high resolution A/D converters. The VRE310 offers superior performance over monolithic references. SELECTION GUIDE Model Initial Error mV VRE310A VRE310B VRE310C VRE310J VRE310K VRE310L 1.0 1.6 2.0 1.0 1.6 2.0 Temp. Coeff. ppm/°C 0.6 1.0 2.0 0.6 1.0 2.0 Temp. Range °C 0°C to +70°C 0°C to +70°C 0°C to +70°C -40°C to +85°C -40°C to +85°C -40°C to +85°C For package option add D for DIP or S for Surface Mount to end of model number. VRE310DS REV. D MAY 2001 ELECTRICAL SPECIFICATIONS VRE310 Vps =+15V, T = 25°C, RL = 10KΩ unless otherwise noted. MODEL A/J PARAMETER MIN TYP +13.5 0 -40 -65 +15 B/K MAX C/L MIN TYP MAX MIN TYP MAX UNITS * * * * * * * * * * * * * * * * * * V °C °C °C ABSOLUTE RATINGS Power Supply Operating Temp. (A,B,C) Operating Temp. (J,K,L) Storage Temperature Short Circuit Protection +22 +70 +85 +150 Continuous * * * * * * OUTPUT VOLTAGE VRE310 (1) Temp. Sensor Voltage 10.000 630 V mV OUTPUT VOLTAGE ERRORS (2) Initial Error Warmup Drift Tmin - Tmax (3) Long-Term Stability Noise (.1-10Hz) (4) 1.00 1.60 1 2.00 2 0.6 3 1.0 6 6 2.0 * * * * mV ppm ppm/°C ppm/1000hrs µVpp OUTPUT CURRENT Range ±10 * * mA REGULATION Line Load 3 3 10 * * * * * * ppm/V ppm/mA OUTPUT ADJUSTMENT Range 20 POWER SUPPLY CURRENTS * mV (5) VRE310 +PS NOTES: * 5 7 *Same as A/J Models. 1. The temp. reference TC is 2.1mV/°C 2. The specified values are without external trim. * * * * mA 4. The specified values are without the external noise reduction capacitor. 5. The specified values are unloaded. 3. The temperature coefficient is determined by the box method using the following formula: Vmax - Vmin x 106 T.C. = Vnominal x (Tmax-Tmin) VRE310DS REV. D MAY 2001 TYPICAL PERFORMANCE CURVES VOUT vs. TEMPERATURE Temperature oC VRE310A VOUT vs. TEMPERATURE Temperature oC VRE310B VOUT vs. TEMPERATURE VOUT vs. TEMPERATURE Temperature oC VRE310J Temperature oC VRE310K QUIESCENT CURRENT VS. TEMP JUNCTION TEMP. RISE VS. OUTPUT CURRENT Temperature oC Output Current (mA) VOUT vs. TEMPERATURE Temperature oC VRE310C VOUT vs. TEMPERATURE Temperature oC VRE310L PSRR VS. FREQUENCY Frequency (Hz) VRE310DS REV. D MAY 2001 DISCUSSION OF PERFORMANCE THEORY OF OPERATION This network is less than 2% of the overall network resistance so it has a negligible effect on long term stability. By using highly stable resistors in our network, we produce a voltage reference that also has very good long term stability The following discussion refers to the schematic in figure 2 below. In operation, approximately 6.3 volts is applied to the noninverting input of the op amp. The voltage is amplified by the op amp to produce a 10.000V output. The gain is determined by the networks R1 and R2: G=1 + R2/R1. The 6.3V zener diode is used because it is the most stable diode over time and temperature. Figure 3 shows the proper connection of the VRE310 series voltage references with the optional trim resistor. The VRE310 reference has the ground terminal brought out on two pins (pin 4 and pin 7) which are connected together internally. This allows the user to achieve greater accuracy when using a socket. Voltage references have a voltage drop across their power supply ground pin due to quiescent current flowing through the contact resistance. If the contact resistance was constant with time and temperature, this voltage drop could be trimmed out. When the reference is plugged into a socket, this source of error can be as high as 20ppm. By connecting pin 4 to the power supply ground and pin 7 to a high impedance ground point in the measurement circuit, the error due to the contact resistance can be eliminated. If the unit is soldered into place, the contact resistance is sufficiently small that it does not effect performance. Pay careful attention to the circuit layout to avoid noise pickup and voltage drops in the lines. The zener operating current is derived from the regulated output voltage through R3. This feedback arrangement provides a closely regulated zener current. This current determines the slope of the references' voltage vs. temperature function. By trimming the zener current a lower drift over temperature can be achieved. But since the voltage vs. temperature function is nonlinear this compensation technique is not well suited for wide temperature ranges. Thaler Corporation has developed a nonlinear compensation network of thermistors and resistors that is used in the VRE series voltage references. This proprietary network eliminates most of the nonlinearity in the voltage vs. temperature function. By then adjusting the slope, Thaler Corporation produces a very stable voltage over wide temperature ranges. VRE310 FIGURE 2 EXTERNAL CONNECTIONS + VIN V TEMP OUT 2 3 8 OPTIONAL NOISE REDUCTION CAPACITOR 6 VRE310 CN 1µF 5 7 FIGURE 3 + VOUT 4 10kΩ OPTIONAL FINE TRIM ADJUSTMENT REF. GND VRE310DS REV. D MAY 2001 MECHANICAL FIGURE 3 D D1 INCHES D2 E1 E2 E PIN 1 IDENTIFIER MILLIMETER MILLIMETER MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 D2 .018 .023 0.46 0.58 B .098 .102 2.48 2.59 E .507 .513 12.8 13.0 B1 .046 .051 1.14 1.29 E1 .397 .403 10.0 10.2 C .107 .113 2.71 2.89 E2 .264 .270 6.70 6.85 C1 .009 .012 0.22 0.30 P .085 .095 2.15 2.41 C2 .052 .058 1.32 1.47 Q .020 .030 .508 .762 S .045 .055 1.14 1.39 D .397 .403 10.0 10.2 D1 .372 .380 9.44 9.65 E1 Q A INCHES DIM P BASE SEATING C1 C2 B S C B1 FIGURE 4 INCHES MILLIMETER INCHES MILLIMETER DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX A .115 .125 2.92 3.17 E .397 .403 10.0 10.2 B .018 .022 .457 .558 E1 .264 .270 6.70 6.85 B1 .046 .051 1.14 1.29 G1 .290 .310 7.36 7.87 B2 .098 .102 2.48 2.59 L .195 .215 4.95 5.46 C .009 .012 0.22 0.30 P .085 .095 2.15 2.41 D .397 .403 10.0 10.2 Q .055 .065 1.39 1.65 D1 .372 .380 9.44 9.65 S .045 .055 1.14 1.39 VRE310DS REV. D MAY 2001