Introduction of the DS1847 for Industrial Controls
DS1847 FeaturesFigure 1 shows a block diagram of the DS1847. The DS1847 operates from a 3V or 5V supply over the temperature range of -40°C to +95°C and offers internal closed loop temperature compensation.
Figure 1. Block diagram.
The DS1847 can operate standalone in closed loop mode without a microcontroller or with a microcontroller using an optional 2-wire master. The 2-wire master allows multiple devices to be controlled in different locations.
Figure 2 shows how multiple DS1847s can be connected to a 2-wire master. The address pins allow up to 8 devices on the 2-wire bus.
Figure 2. 2-Wire interface.
Temperature CompensationOne of the benefits of the DS1847 is the internal closed loop temperature compensation. Since the resistor settings and memory are nonvolatile, a microprocessor is not needed when using the DS1847.
With the ability to program the resistance as a function of temperature, the user can create a very low tempco resistor. The compensated tempco error is ±4 LSB. A transfer function can be programmed into the resistor lookup table (LUT) to fit many applications. The resistor LUT is EEPROM memory that can contain a unique resistor value at a specific temperature from -40°C to +95°C in 2°C increments. See the DS1847 Operation section for more information on the LUT.
The resistor outputs can also be used as digital outputs to drive external circuitry. The outputs can be used as alarms or as general-purpose digital outputs. The DS1847 can be configured to output a resistance, voltage, or current.
DS1847 OperationThe DS1847 has a LUT that determines the resistor value at a specific temperature (see Figure 3). First, after a 10ms conversion time, the internal temperature sensor senses the ambient temperature. This temperature determines the LUT address. If the temperature sensed is -38°C, the corresponding address is 01h. The resistance value in address location 01h is used to adjust the resistance.
Figure 3. Lookup table.
Using the DS1847 with Industrial ControlsThe DS1847 can be beneficial in industrial control applications. First, the temperature-controlled resistor can provide a relatively constant resistance over temperature or the resistance can be set to increase or decrease with temperature.
Figure 4 shows how the DS1847 can be connected to a fixed resistor to create a voltage divider (Vout0). This will provide a fixed or variable output voltage to an application over temperature. A transfer function can be programmed into the LUT to change the voltage with temperature.
Figure 4. Voltage and digital outputs.
The DS1847 can also be configured to create a digital output (Vout1). Using a fixed resistance of 4.7kΩ and the 50kΩ variable resistor, the output voltage range is 0.77V to 4.57V (see Example 1). The digital output can be used as an alarm or warning when the temperature reaches a certain value (see the Voltage Alarm Example). The digital output can be set to go low or high if the temperature changes from the set value or if the temperature exceeds a certain value.
Voltage Alarm ExamplesTo set the voltage to go high when a specific temperature is reached, 94°C in this illustration (see Figure 5), the LUT would be programmed to set the resistor to the minimum position (position 0) for the temperature range -40°C to 92°C. For temperatures 94°C and above the resistor position would be set to FFh.
Figure 5. Lookup table for a voltage alarm.
Design ConsiderationsWhen using the DS1847 as a voltage divider or a digital output, the fixed resistor value needs to be calculated (see Figure 6).
If the DS1847 will be configured as a digital output, the output voltage needs to meet the VIH and VIL levels of the digital circuitry. Equation 1 shows how to calculate the output voltage at a certain fixed resistance.
Where, Vin = Vcc = 5V
Figure 6. Voltage divider.
Using Equation 1 and the Rmin and Rmax of the 50kΩ resistor, the output voltage range is calculated.
Using a 4.7kΩ resistor, the output voltage range is 0.77V to 4.57V over the resistor range of the 50kΩ resistor.