SBOA575 September   2023 INA823 , OPA2387 , XTR115 , XTR116

 

  1.   1
  2.   Abstract
  3.   Trademarks
  4. 1Introduction
  5. 2Theory of Operation
    1. 2.1 Wheatstone Bridge Sensor
    2. 2.2 2-Amp INA
    3. 2.3 4-20-mA Current Loop Transmitter Interface
  6. 3Simulation
  7. 4PCB Design
  8. 5Verification and Measured Performance
  9. 6Summary
  10. 7Reference
  11.   Appendix

2.2 2-Amp INA

A discrete 2-amp INA is selected to amplify the differential voltage developed by the bridge. A discrete solution is selected over an integrated INA because a wide gain range and zero-drift technology for high precision over temperature is required. The circuit configuration and transfer function are shown below in Figure 2-4 and Equation 4 respectively.

GUID-20230817-SS0I-VM90-NG3J-RCQ5VTVJC2DM-low.svg Figure 2-4 Discrete 2-Amp INA Configuration
Equation 4. V o u t _ I N A = 1 + R 3 R 2 + 2 R 2 R G * V 2 - V 1 + V R E F ,           w h e r e   R 1 = R 2   a n d   R 3 = R 4

Experimentation with the load cell showed a change in VDIFF of approximately 95-μV/lb. Hence, a gain stage is necessary to increase the output voltage to an appropriate range to feed into the 4-20-mA transmitter. The gain of the 2-amp INA is calculated below. The desired output voltage of the INA is 0.5-V at 0-lbs and 4.5-V at 20-lbs.

Equation 5. VDIFF_MAX=sensitivity×maxload=95μV/lb×20lbsVDIFF_MAX=1.9mV 
Equation 6. G a i n = ( V o u t m a x _ I N A - V o u t m i n _ I N A ) V D I F F _ M A X = 4.5   V - 0.5   V 1.9   m V G a i n =   2105   V / V

The required gain is used to calculate the resistor values of the 2-amp INA. R1 and R2 are set to 100 kΩ and R3 and R4 are set to 10 kΩ.

Equation 7. R G = 2 * R 2 G a i n - 1 - R 3 R 2     = 2 * 100 k Ω 2105 V / V - 1 - 100 k Ω 10 k Ω = 95.511 Ω R G = 95.3 Ω   ( s t a n d a r d   v a l u e )
Equation 8. Gain=1+R3R2+2R2RG,     where R1=R2 and R3=R4

DC precision and noise are key considerations when choosing an amplifier for bridge sensing. Low input offset voltage, drift and input bias current are vital to achieve a high accuracy output. An amplifier with low 1/f noise is important because bridge sensors are typically used with low signal frequencies. The OPA2387 with Zero-Drift Amplifiers: Features and Benefits, application brief is selected for the 2-amp INA. Table 2-1 summarizes the key specifications for the bridge amplifier stage and suggests other precision amplifiers that are designed for this application.

Table 2-1 Key Specifications for Bridge Amplifier Device
DeviceOPAx387OPAx333OPAx186
Supply (V)1.7 to 5.51.8 to 5.54.5 to 24
Vos (max, μV)2105
Vos drift (typ, nV/°C)3201
Input bias current (typ, pA)3070100
Noise (0.1 to 10 Hz, nV/√Hz)27170125
Iq per channel (typ, μA)5701790

The output voltage of the 2-amp INA is approximately 0.345-V when no weight is applied to the load cell. Therefore, a reference of 0.155-V is implemented to boost the output voltage up to 0.5-V at 0-lbs. TI’s Analog Engineer’s Calculator can be used to calculate the standard resistor values that offer the lowest possible reference voltage error.

The reference voltage of the INA (VREF INA) is set using a voltage divider between the 4.096-V XTR reference and the local ground where the series resistance must be in the 10’s of kΩ to limit current consumption. VREF INA must be driven with a low-impedance source to prevent a voltage drop due to the input resistor, R1. The TLV333 was selected to buffer the reference voltage due to its low power consumption and high DC precision.

Equation 9. VREF_INA=0.155V=VREF_XTR×RB2RB1+RB2  RB1=76.8kΩ, RB2=3.01kΩ