Measuring Temperature with the

Measuring Temperature with the MAX1358 Data Acquisition System

Abstract: This application note explains how to use the internal and external temperature sensors on the MAX1358 data acquisition system. The temperature circuits for the MAX1358/MAX1359/MAX1360 are identical, therefore any reference to the MAX1358 also applies to the MAX1359 and MAX1360. A step-by-step approach guides the user through the setup, measurement, and calculation of the temperature.

Introduction

The MAX1358 data acquisition system can measure temperature using an internal or external transistor PN junction. Figure 1 shows the internal temperature circuit and the external circuit. A constant current is supplied by the current source to produce a voltage (V_BE) across the transistor. The current source can be programmed to produce up to four currents. For each current the voltage drop across the transistor is measured using the integrated ADC. The ADC has inputs for TEMP+, TEMP-, AIN1, AIN2, and AGND. These measured values are used in an equation to determine the junction temperature.

Figure 1. MAX1358 internal/external temperature measurement circuit.

Internal Four-Current Method

The internal four-current method requires eight measurements to be used in the temperature-measurement equation. Equation 1 below is used for four-current measurement.

Equation 1. Four-current temperature measurement equation.

Substituting for I₁, I₂, I₃, and I₄ in the denominator:

Equation 1 substitution

Where:
T_MEAS = temperature in Kelvin
q = electron Charge = 1.60219 × 10^-19 Coulombs
NV_BE1 = ADC reading with I₁ as current source
NV_BE2 = ADC reading with I₂ as current source
NV_BE3 = ADC reading with I₃ as current source
NV_BE4 = ADC reading with I₄ as current source
V_REF = ADC reference voltage = 1.251V (typ)
n = diode ideality = 1.000 (typ)
k = Boltzmann's constant = 1.3807 × 10^-23 Joules/Kelvin
I₁ = Current source low setting (4µA)
I₂ = Current source high setting (60µA)
I₃= Current source high setting (64µA)
I₄ = Current source high setting (120µA)
NV_R1 = ADC reading with I₁ as current source
NV_R2 = ADC reading with I₂ as current source
NV_R3 = ADC reading with I₃ as current source
NV_R4 = ADC reading with I₄ as current source
2¹⁶ = Number of ADC steps for MAX1358 16-bit ADC

To convert the measured temperature in Kelvin to degrees Celsius, the following formula is used:

°C = K - 273.15

Procedure Using the Internal Transistor

The procedure for measuring the voltages across the internal transistor and internal resistor applies a current from the current source, and measures the resulting V_BE and V_R.

Step 1. Enable the Reference and ADC

Enable the internal 1.251V reference and the reference buffer with a gain of 1.0 by setting REFV[1:0] bits to 0x01 in the REF_SDC register.

Enable the ADC by setting the ADCE bit in the ADC register. The internal reference and ADC are enabled. Note: The ADC is set with the default parameters of unipolar, normal polarity, single conversion, internal reference, unity gain, 10 samples per second, and normal conversion.

Step 2. Calibrate the ADC

Set the ADC conversion mode to Self Offset and Gain Calibration by setting the Mode[2:0] bits to 0x07 in the ADC register. Start an ADC conversion by setting the STRT bit in the ADC register. The ADC is now calibrated. The Mode[2:0] bits in the ADC register are automatically cleared. This returns the ADC to normal operation.

Step 3. Set the Current Source for the Internal Temperature Sensor

Set the current source for the internal temperature sensor by setting the IMUX[1:0] bits to 0x01 in the TEMP_CTRL register.

Step 4. Set the Current Source for I₁ (4µA)

Set the current source for I₁ by setting the IVAL[1:0] bits to 0x00 in the TEMP_CTRL register.

Step 5. Set the ADC Input for TEMP+ to TEMP-

Set the ADC positive input multiplexer for TEMP+ by setting MUXP[3:0] to 0x07 in the MUX register. Set the ADC negative multiplexer for TEMP- by setting MUXN[3:0] to 0x00 in the MUX register.

Step 6. Measure V_BE1 using the ADC

The V_BE1 voltage is measured from the TEMP+ to the TEMP- inputs to the ADC. The ADC is already configured and only needs to convert to get the resulting V_BE1 voltage. To start the ADC conversion, set the STRT bit in the ADC register. The ADC will do a conversion and the result will be in the DATA register. Read the DATA register value and save as a 16-bit integer named VBE1 for later calculation.

Step 7. Set the ADC Input for V_R1

Set the ADC positive input multiplexer for AGND by setting MUXP[3:0] to 0x09 in the MUX register. Set the ADC negative multiplexer for TEMP- by setting MUXN[3:0] to 0x00 in the MUX register (same as step 5). To measure the TEMP- input relative to AGND, the polarity flipper bit is used. Set the POL bit in the ADC register. The ADC is now setup with TEMP- as its positive input and AGND as its negative input.

Step 8. Measure V_R1 using the ADC

To start the ADC conversion, set the STRT bit in the ADC register. The ADC will do a conversion and the result will be in the DATA register. Read the DATA register value and save as a 16-bit integer named VR1 for later calculation.

Step 9. Set the Current Source for I₂ (60µA)

Set the current source for I₂ by setting the IVAL[1:0] bits to 0x01 in the TEMP_CTRL register.

Step 10. Set the ADC Input for TEMP+ to TEMP-

Set the polarity flipper back to normal by clearing the POL bit in the ADC register. Set the ADC positive input multiplexer for TEMP+ by setting MUXP[3:0] to 0x07 in the MUX register. Set the ADC negative multiplexer for TEMP- by setting MUXN[3:0] to 0x00 in the MUX register.

Step 11. Measure V_BE2 using the ADC

The V_BE2 voltage is measured from the TEMP+ to the TEMP- inputs to the ADC. The ADC is already configured and only needs to convert to get the resulting V_BE2 voltage. To start the ADC conversion, set the STRT bit in the ADC register. The ADC will do a conversion and the result will be in the DATA register. Read the DATA register value and save as a 16-bit integer named VBE2 for later calculation.

Step 12. Set the ADC Input for V_R2

Step 13. Measure V_R2 using the ADC

Step 14. Set the Current Source for I₃ (64µA)

Set the current source for I₃ by setting the IVAL[1:0] bits to 0x10 in the TEMP_CTRL register.

Step 15. Set the ADC Input for TEMP+ to TEMP-

Step 16. Measure V_BE3 Using the ADC

The V_BE3 voltage is measured from the TEMP+ to the TEMP- inputs to the ADC. The ADC is already configured and only needs to convert to get the resulting V_BE3 voltage. To start the ADC conversion, set the STRT bit in the ADC register. The ADC will do a conversion and the result will be in the DATA register. Read the DATA register value and save as a 16-bit integer named VBE3 for later calculation.

Step 17. Set the ADC Input for V_R3

Step 18. Measure V_R3 Using the ADC

Step 19. Set the Current Source for I₄ (120µA)

Set the current source for I₄ by setting the IVAL[1:0] bits to 0x11 in the TEMP_CTRL register.

Step 20. Set the ADC Input for TEMP+ to TEMP-

Step 21. Measure V_BE4 Using the ADC

The V_BE4 voltage is measured from the TEMP+ to the TEMP- inputs to the ADC. The ADC is already configured and only needs to convert to get the resulting V_BE4 voltage. To start the ADC conversion, set the STRT bit in the ADC register. The ADC will do a conversion and the result will be in the DATA register. Read the DATA register value and save as a 16-bit integer named VBE4 for later calculation.

Step 22. Set the ADC Input for V_R4

Step 23. Measure V_R4 using the ADC

Step 24. Calculate the Temperature

The temperature is calculated using the formula in Equation 1 above. The equation can be simplified by multiplying and dividing the constants in advance. The constant is applied to Equation 2 shown below.

Equation 2. Simplified four-current temperature measurement equation.

Four-Current Method Example Using Real Data

The temperature was measured on an evaluation (EV) kit at room temperature using the procedure above with the following results.

For I₁ 4µA	NV_BE1 = 0x81AF	NV_R1 = 0x0350
For I₂ 60µA	NV_BE2 = 0x9048	NV_R2 = 0x32D4
For I₃ 64µA	NV_BE3 = 0x90A5	NV_R3 = 0x3629
For I₄ 120µA	NV_BE4 = 0x93E2	NV_R4 = 0x615c

Using Equation 2 above and substituting the measured values:

Equation 2 substitution

Solving the equation for the temperature yields: T_MEAS = 300.19K
Converting the result from Kelvin to Celsius yields: °C = 300.19 - 273.15 = 27.04°C

This is the measured value at room temperature. A correction for gain and offset has not been applied. The gain and offset correction is detailed below.

External Four-Current Method

The external four-current method is the same as the internal four-current method, except that the internal current-source multiplexer must be changed to direct the current source out AIN1 or AIN2. The ADC input multiplexer must also be changed to use AIN1 and AIN2 as the ADC inputs.

The external components are connected as shown in Figure 1 above. The external transistor chosen for this application is a low-cost surface-mount 2N3904 from On Semiconductor, part number MMBT2N3904LT1. Other transistors or diodes can also be selected. The resistor chosen is a low-cost surface-mount 4.02K 1% size 0805 1/8 watt from Panasonic®, part number ERJ-6ENF4021V. This value resistor was chosen to match the internal resistor, which is typically 4KΩ.

Procedure Using the External Transistor

The procedure for measuring the voltages across the external transistor and external resistor is similar to the internal four-current method, except that the current source must be selected to drive AIN1 or AIN2 and different inputs must be selected to read the external V_BE and V_R.