VRE3050LD - Thaler Corporation

VRE3050

Low Cost

Precision Reference

DESCRIPTION

FEATURES

The VRE3050 is a low cost, high precision 5.0V

reference that operates from +10V. The device

features a buried zener for low noise and excellent

long term stability. Packaged in an 8 pin DIP and

SMT, the device is ideal for high resolution data

conversion systems.

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 VRE3050 series

the most accurate reference available.

For enhanced performance, the VRE3050 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.

VRE3050

TOP

VIEW

N/C

+VIN

N/C

GND

NOISE

REDUCTION

VOUT

TRIM

PIN CONFIGURATION

The VRE3050 is recommended for use as a

reference for 14, 16, or 18 bit data converters

which require an external precision reference.

The device is also ideal for calibrating scale factor

on high resolution data converters. The VRE3050

offers superior performance over monolithic

references.

•5.000 V Output ± 0.500 mV (.01%)

•Temperature Drift: 0.6 ppm/°C

•Low Noise: 3µV p-p(0.1Hz-10Hz)

•Low Thermal Hysterisis: 1 ppm Typ.

•±15mA Output Source and Sink Current

•Excellent Line Regulation: 5 ppm/V Typ.

•Optional Noise Reduction and Voltage Trim

•Industry Standard Pinout FIGURE 1

VRE3050DS REV. D JULY 2000

SELECTION GUIDE

Model Temp.

Range °C

Temp.

Coeff.

ppm/°C

VRE3050A 0.5 0.6 0°C to +70°C

VRE3050B 0.8 1.0 0°C to +70°C

VRE3050C 1.0 2.0 0°C to +70°C

VRE3050J 0.5 0.6 -40°C to +85°C

VRE3050K 0.8 1.0 -40°C to +85°C

VRE3050L 1.0 2.0 -40°C to +85°C

For package option add D for DIP or S for Surface Mount

to end of model number.

Initial

Error

THALER CORPORATION • 2015 N. FORBES BOULEVARD • TUCSON, AZ. 85745 • (520) 882-4000

N/C

ppm/

1khrs

6∆VOUT/t

Long Term Stability

µVp-p3.00.1Hz<f<10Hz

Output Noise Voltage

µs2 To 0.01% of final valueTon

Turn-On Settling Time

mV±5Figure 3∆VOUT

Trim Adjustment Range

1.0 2.0VRE3050C/K

0.5 1.0VRE3050B/K

4.9990 5.0000 5.0010VRE3050C/L

4.9992 5.0000 5.0008VRE3050B/K V

4.9995 5.0000 5.0005VRE3050A/J

VOUT

Output Voltage

(Note 1)

5 1010V ≤VIN ≤18V ppm/V

25 358V ≤VIN ≤10V

∆VOUT/

∆VIN

Line Regulation

(Note 3)

ppm/

8 12

Sourcing:

0mA ≤IOUT ≤15mA

Sinking:

-15mA ≤IOUT ≤0mA

∆VOUT/

∆IOUT

Load Regulation

(Note 3)

mA3.5 4.0IIN

Supply Current

µVRMS

2.5 5.010Hz<f<1kHz

ppm1Note 4Temperature Hysterisis

ppm/°C

0.3 0.6VRE3050A/J

TCVOUT

Output Voltage

Temperature Coefficient

(Note 2)

V8 36VIN

UNITSMIN TYP MAXSYMBOL CONDITIONS

Input Voltage

PARAMETER

ELECTRICAL SPECIFICATIONS

Vps =+10V, T = 25°C, Iout=0mA unless otherwise noted.

Notes:

1) The specified values are without external trim.

2) The temperature coefficient is determined by the

box method. See discussion on temperature

performance.

3) Line and load regulation are measured with pulses and

do not include voltage changes due to temperature.

4) Hysterisis over the operating temperature range.

VRE3050DS REV. D JULY 2000

ABSOLUTE MAXIMUM RATINGS

Power Supply ………………………-0.3V to +40V Out Short Circuit to GND Duration (VIN< 12V)…...Continuous

OUT, TRIM …………………………-0.3V to +12V Out Short Circuit to GND Duration (VIN< 40V)…….……5 sec

NR……………………………………-0.3V to +6V Out Short Circuit to IN Duration (VIN< 12V)………Continuous

Operating Temp. (A,B,C)……………0°C to 70°C Continuous Power Dissipation (TA= +70°C)………...300mW

Operating Temp. (J,K,L)……………-40°C to 85°C Storage Temperature……………………..……-65°C to 150°C

Lead Temperature (soldering,10 sec)…………………..250°C

TYPICAL PERFORMANCE CURVES

Temperature (oC)

VRE3050A

VOUT vs. TEMPERATURE

VRE3050DS REV. D JULY 2000

SUPPLY CURRENT

VS. SUPPLY VOLTAGE QUIESCENT CURRENT VS. TEMP

Temperature (oC)

OUTPUT IMPEDIANCE

VS. FREQUENCY

Temperature (oC)

VRE3050B

VOUT vs. TEMPERATUREVOUT vs. TEMPERATURE

Temperature (oC)

VRE3050C

Temperature (oC)

VRE3050J

VOUT vs. TEMPERATURE

Temperature (oC)

VRE3050K

VOUT vs. TEMPERATURE

Temperature (oC)

VRE3050L

VOUT vs. TEMPERATURE

Supply Voltage (V)

Supply Current (mA)

Frequency (Hz)

∆Vout (mV)

Quiescent Current (mA)

Output Impediance ( Ω)

-50

100

6.0

4.0

2.0

8.0

5.0

4.0

3.0

6.0

-50

-25

100

2.0

1.5

1.0

0.5

-1.0

-0.5

-1.5

-2.0

Lower Limit

Upper Limit

-50

-25

100

2.0

1.5

1.0

0.5

-1.0

-0.5

-1.5

-2.0

Lower Limit

Upper Limit

1.00

0.75

0.50

0.25

-0.50

-0.25

-0.75

-1.00

Lower Limit

Upper Limit

1.00

0.75

0.50

0.25

-0.50

-0.25

-0.75

-1.00

Lower Limit

Upper Limit

Lower Limit

Upper Limit

-0.75

1.00

0.75

0.50

0.25

-0.50

-0.25

-1.00

Lower Limit

Upper Limit

-50

-25

100

2.0

1.5

1.0

0.5

-1.0

-0.5

-1.5

-2.0

Lower Limit

Upper Limit

TYPICAL PERFORMANCE CURVES

RIPPLE REJECTION

Vs. FREQUENCY(CNR=0µF)

OUTPUT NOISE-VOLTAGE

DENSITY vs. FREQUENCY

VRE3050DS REV. D JULY 2000

TURN-ON AND TURN-OFF

TRANSIENT RESPONSE

JUNCTION TEMP. RISE VS.

OUTPUT CURRENT

Output Current (mA)

CHANGE IN OUTPUT VOLTAGE

VS. INPUT VOLTAGE

CHANGE IN OUTPUT VOLTAGE

VS. OUTPUT CURRENT

Vin(V)

Vout (ppm)

Iout(mA)

Vout (µV)

Frequency (Hz)

Vcc = 1

-20

-10

Ripple Rejection (dB)

Junction Temperature

Rise Above Ambient (oC)

Output Noise Density (nV/√Hz)

-200

-400

-300

-100

100

200

300

400

1 µs/div

+10V

A: Vin, 10V/div

B: Vout, 1V/div

10k

100

10k

100

0.1Hz to 10Hz Noise

∆Vout, 1µV/Div

1 Sec/Div

VRE3050DS REV. D JULY 2000

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.

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.

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

VRE3050 series voltage references with the optional trim

resistor for initial error and the optional capacitor for noise

reduction.

BASIC CIRCUIT CONNECTION

Figure 3 shows the proper connection of the VRE3050

voltage reference with the optional trim resistor for initial

error and the optional capacitor for noise reduction.

To achieve the specified performance, pay careful

attention to the layout. A low resistance star configuration

will reduce voltage errors, noise pickup, and noise

coupled from the power supply. Commons should be

connected to a single point to minimize interconnect

resistances.

Figure 3 External Connections

+VOUT

+ VIN

VRE3050

10kΩ

CN 1µF

Optional Noise

Reduction

Capacitor Optional Fine

Trim Adjustment

Figure 2 Functional Block Diagram

Noise ReductionNR8

Voltage reference outputOUT6

External trim input. Leave open if

not used.

TRIM5

GroundGND4

Positive power supply input

Internally connected. Do not use

Vin

N.C.

1,3,7

PIN DESCRIPTION

VRE3050DS REV. D JULY 2000

TEMPERATURE PERFORMANCE

The VRE3050 is designed for applications where the

initial error at room temperature and drift over

temperature are important to the user. For many

instrument manufacturers, a voltage reference with a

temperature coefficient less than 1ppm/°Cmakes it

possible to not perform a system temperature calibration,

a slow and costly process.

Of the three TC specification methods (slope, butterfly,

and box), the box method is most commonly used. A box

is formed by the min/max limits for the nominal output

voltage over the operating temperature range. The

equation follows:

This method corresponds more accurately to the

method of test and provides a closer estimate of actual

error than the other methods. The box method

guarantees limits for the temperature error but does not

specify the exact shape and slope of the device under

test.

A designer who needs a 14-bit accurate data

acquisition system over the industrial temperature range

(-40°C to +85°C), will need a voltage reference with a

temperature coefficient (TC) of 1.0ppm/°C if the reference

is allowed to contribute an error equivalent to 1LSB. For

1/2LSB equivalent error from the reference you would

need a voltage reference with a temperature coefficient of

0.5ppm/°C. Figure 4 shows the required reference TC vs.

delta T change from 25°C for resolution ranging from 8

bits to 20 bits.

THERMAL HYSTERISIS

A change in output voltage as a result of a temperature

change. When references experience a temperature

change and return to the initial temperature, they do not

always have the same initial voltage. Thermal hysterisis

is difficult to correct and is a major error source in

systems that experience temperature changes greater

than 25°C. Reference vendors are starting to include this

important specification in their datasheets.

( )

minmaxnominal

minmax 10.. •











−•−

=TTVVV

0.01

0.1

100

1000

10000

1 10 100

20 BIT

18 BIT

16 BIT

14 BIT

12 BIT

10 BIT

8 BIT

ReferenceTC

(ppm/°C)

Reference TC vs. ∆T change from 25°C for 1 LSB change

VRE3050DS REV. D JULY 2000

MECHANICAL SPECIFICATIONS

INCHES MILLIMETER

DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX

A.110 .120 2.794 3.048 D1 .372 .380 9.45 9.65

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

INCHES MILLIMETER

E2 E1 E

CC2

VRE3050DS REV. D JULY 2000

MECHANICAL SPECIFICATIONSMECHANICAL SPECIFICATIONS

E2 E1 E

INCHES MILLIMETER

DIM MIN MAX MIN MAX DIM MIN MAX MIN MAX

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 9.45 9.65 S.045 .055 1.14 1.40

INCHES MILLIMETER