Analog and Interface Product Solutions Signal Chain Design Guide Devices For Use With Sensors Design ideas in this guide use the following devices. A complete device list and corresponding data sheets for these products can be found at www.microchip.com/analog. Operational Amplifiers MCP6XX MCP6XXX MCP6V01/2/3 MCP6V06/7/8 Comparators MCP654X MCP656X Analog-to-Digital Converters MCP3421 MCP3422/3/4 MCP355X MCP3901 Temperature Sensors MCP9800 MCP9804 MCP9700/A MCP9701/A Voltage References MCP1525 MCP1541 Digital Potentiometers MCP40XX MCP40D1X MCP41XX MCP42XX MCP43XX MCP45XX MCP46XX MCP41XXX MCP42XXX Digital-to-Analog Converters MCP4725 MCP4728 MCP482X MCP492X www.microchip.com/analog Signal Chain Overview Typical sensor applications involve the monitoring of sensor parameters and controlling of actuators. The sensor signal chain, as shown below, consists of analog and digital domains. Typical sensors output very low amplitude analog signals. These weak analog signals are amplified and filtered, and converted to digital using op amps, an analog-to-digital or voltage-to-frequency converter, and is processed at the MCU. The analog sensor output typically needs proper signal conditioning before it gets converted to a digital signal. The MCU controls the actuators and maintains the operation of the sensor signal conditioning circuits based on the condition of the signal detection. For the digital to analog feedback path, the digital-to-analog converter (DAC), digital potentiometer and Pulse-Width-Modulator (PWM) devices are most commonly used. The MOSFET driver is commonly used for the interface between the feedback circuit and actuators such as motors and valves. Microchip offers a large portfolio of devices for signal chain applications. Typical Sensor Signal Chain Control Loop Analog Domain Digital Domain Sensors Indicator (LCD, LED) Reference Voltage MUX Filter ADC/ V-to-Freq Op Amp PIC(R) MCU or dsPIC(R) DSC Digital Potentiometer Actuators Motors, Valves, Relays, Switches, Speakers, Horns, LEDs 2 Signal Chain Design Guide Driver (MOSFET) Op Amp DAC/PWM Sensor Overview Many system applications require the measurement of a physical or electrical condition, or the presence or absence of a known physical, electrical or chemical quantity. Analog sensors are typically used to indicate the magnitude or change in the environmental condition, by reacting to the condition and generating a change in an electrical property as a result. Typical phenomena that are measured are: Electrical Signal and Properties Magnetic Signal and Properties Temperature Humidity Force, Weight, Torque and Pressure Motion and Vibration Flow Fluid Level and Volume Light and Infrared Chemistry/Gas There are sensors that respond to these phenomena by producing the following electrical properties: Voltage Current Resistance Capacitance Charge This electrical property is then conditioned by an analog circuit before being converted to a digital circuit. In this way, the environmental condition can be "measured" and the system can make decisions based on the result. The table below provides an overview of typical phenomena, the type of sensor commonly used to measure the phenomena and electrical output of the sensor. For additional information, please refer to Application Note AN990. Summary Of Common Physical Conditions and Related Sensor Types Phenomena Magnetic Temperature Humidity Force, Weight, Torque, Pressure Motion and Vibration Flow Fluid Level and Volume Light Chemical Sensor Hall Effect Magneto-Resistive Thermocouple RTD Thermistor IC Infrared Thermopile Capacitive Infrared Strain Gauge Load Cell Piezo-electric Mechanical Transducer LVDT Piezo-electric Microphone Ultrasonic Accelerometer Magnetic Flowmeter Mass Flowmeter Ultrasound/Doppler Hot-wire Anemometer Mechanical Transducer (turbine) Ultrasound Mechanical Transducer Capacitor Switch Thermal Photodiode pH Electrode Solution Conductivity CO Sensor Photodiode (turbidity, colorimeter) Electrical Output Voltage Resistance Voltage Resistance Resistance Voltage Current Voltage Capacitance Current Resistance/Voltage Resistance Voltage or Charge Resistance, Voltage, Capacitance AC Voltage Voltage or Charge Voltage Voltage, Resistive, Current Voltage Voltage Resistance/Voltage Frequency Resistance Voltage Time Delay Resistance, Voltage Capacitance On/Off Voltage Current Voltage Resistance/Current Voltage or Charge Current Signal Chain Design Guide 3 Product Overviews Operational Amplifiers (Op Amps) Analog-to-Digital Converters (ADC) Microchip Technology offers a broad portfolio of op amp families built on advanced CMOS technology. These families are offered in single, dual and quad configurations, which are available in space saving packages. These op amp families include devices with Quiescent Current (IQ) per amplifier between 0.6 A and 6 mA, with a Gain Bandwidth Product (GBWP) between 10 kHz and 60 MHz, respectively. The op amp with lowest supply voltage (VDD) operates between 1.4V and 6.0V, while the op amp with highest VDD operates between 6.5V and 16.0V. These op amp families fall into the following categories: General Purpose, Low Offset, Auto-zeroed, High Speed, Low Noise and mCal (self calibrating input offset voltage (VOS)). Microchip offers a broad portfolio of high-precision Delta-Sigma, SAR and Dual Slope A/D Converters. The MCP3550/1/3 Delta-Sigma ADCs offer up to 22-bit resolution with only 120 A typical current consumption in a small 8-pin MSOP package. The MCP3421 is a single channel Delta-Sigma ADC and is available in a small 6-pin SOT-23 package. It includes a voltage reference and PGA. The user can select the conversion resolution up to 18 bits. The MCP3422/3 and the MCP3424 are two channel and four channel versions, respectively, of the MCP3421 device. The MCP300X (10-bit), MCP320X (12-bit) and MCP330X (13-bit) SAR ADCs combine high performance and low power consumption in a small package, making them ideal for embedded control applications. The TC5XX Dual Slope ADC devices offer another alternative with up to 17-bits of conversion resolution. The "Analog-to-Digital Converter Design Guide" (Microchip Document No. 21841) shows various application examples of the ADC devices. Microchip also offers many high accuracy energy metering devices which are based on the Delta-Sigma ADC cores. The "Complete Utility Metering Solution Guide" (Microchip Document No: 24930) offers detailed solutions for metering applications. Comparators The MCP6541 and MCP6561 family of comparators provide ultra low power, 600 nA typical, and higher speed with 40 ns propagation delay, respectively. The MCP6541 family low operating current is suitable for battery powered application and the output drive capability is ideal for alert buzzer driver applications. The MCP6561 family with greater than 4 MHz toggle frequency is ideal for higher speed embedded system applications where sinusoidal output from sensors to square wave conversion is needed. The 47 ns typical propagation delay also makes this device ideal for microprocessor interface. Both families of comparators are available with single, dual and quad as well as with push-pull and open-drain output options (MCP6546 and MCP6566). Programmable Gain Amplifier (PGA) The MCP6S21/2/6/8 and MCP6S91/2/3 PGA families give the designer digital control over an amplifier using a serial interface (SPI bus). An input analog multiplexer with 1, 2, 6 or 8 inputs can be set to the desired input signal. The gain can be set to one of eight non-inverting gains: +1, 2, 4, 5, 8, 10, 16 and 32 V/V. In addition, a software shutdown mode offers significant power savings for portable embedded designs. This is all achieved in one simple integrated part that allows for considerably greater bandwidth, while maintaining a low supply current. Systems with multiple sensors are significantly simplified. The MCP6G01 family are analog Selectable Gain Amplifiers (SGA). The Gain Select input pin(s) set a gain of +1 V/V, +10 V/V and +50 V/V. The Chip Select pin on the MCP6G03 puts it into shutdown to conserve power. 4 Signal Chain Design Guide Voltage References Microchip offers the MCP15XX family of low power and low dropout precision Voltage References. The family includes the MCP1525 with an output voltage of 2.5V and the MCP1541 with an output voltage of 4.096V. Microchip's voltage references are offered in SOT23-3 and TO-92 packages. Product Overviews Digital Potentiometers Digital-to-Analog Converters (DAC) Microchip's family of digital potentiometers offer a wide range of options. These devices support the 6-bit through 8-bit applications. Offering both volatile and non-volatile options, with digital interfaces from the simple Up/ Down interface to the standard SPI and I2CTM interfaces. These devices are offered in small packages such as 6-lead SC70 and 8-lead DFN for the single potentiometer devices, 14-lead TSSOP and 16-lead QFN packages for the dual potentiometer devices, and 20-lead TSSOP and QFN packages for the quad potentiometer devices. Non-volatile devices offer a WiperlockTM Technology feature, while volatile devices will operate down to 1.8V. Resistances are offered from 2.1 k to 100 k. Over 50 device configurations are currently available. The "Digital Potentiometer Design Guide" (Microchip Document No. 22017), shows various application examples of the digital potentiometer devices. Microchip has a number of Digital-to-Analog Converters that range from high performance 12-bit devices to cost effective 8-bit devices. The MCP4725 is a single channel 12-bit DAC with nonvolatile memory (EEPROM). The user can store DAC input code and configuration register bits into the EEPROM. This non-volatile memory feature enables the device to hold the DAC input code during power-off time allowing the DAC output to be available immediately after power-up. This feature is very useful when the DAC is used as a supporting device for other device operations in systems. The MCP4725 is availabe in a tiny SOT23-6 package. The MCP4728 is a 12-bit DAC with four analog outputs. This device also has non-volatile memory (EEPROM) for each DAC channel. The user can select internal reference or VDD as reference individually for each channel. The MCP4725 and MCP4728 are available with I2C serial interface. The MCP4821/2 family of 12-bit DACs combines high performance with an internal reference voltage and SPI interface. The MCP4921/2 family is similar and allows for an external reference. These DAC devices provide high accuracy and low noise, and are ideal for industrial applications where calibration or compensation of signals (such as temperature, pressure and humidity) is required. The TC1320/1 family of DACs has 8- and 10-bit precision that uses the 2-wire SMBus/I2C serial interface protocol. Signal Chain Design Guide 5 Local Sensors Local Sensing Sensors and Applications Local sensors are located relatively close to their signal conditioning circuits, and the noise environment is not severe; most of these sensors are single ended (not differential). Non-inverting amplifiers are a good choice for amplifying most of these sensors' output because they have high input impedance, and require a minimal amount of discrete components. Single Sensors Thermistors for battery chargers and power supply temperature protection Humidity Sensors for process control Pyroelectric infrared intrusion alarms, motion detection and garage door openers Smoke and fire sensors for home and office Charge amplifier for Piezoelectric Transducer detection Thermistor for battery chargers and home thermostats LVDT position and rotation sensors for industrial control Hall effect sensors for engine speed sensing and door openers Photoelectric infrared detector Photoelectric motion detectors, flame detectors, intrusion alarms Key Amplifier Features Low Cost - General Purpose Op Amps High Precision - Low Offset Op Amps - Auto-zeroed Op Amps - Low Noise Op Amps Rail-to-Rail Input/Output - Most Op Amp families High Input Impedance - Almost all Op Amp families Low Power and Portable Applications - Low Power Op Amps High Bandwidth and Slew Rate - High Speed Op Amps Load Drive - High Output Drive Op Amps Multiple Local Sensors Temperature measurement at multiple points on a Printed Circuit Board (PCB) Sensors that require temperature correction Weather measurements (temperature, pressure, humidity, light) Capacitive Humidity Sensor Circuit (PIC16F690DM-PCTLHS) Classic Gain Amplifier VDD_DIG C1 100 nF U1 PIC16F690 P1 VINT RINT R6.65 M IINT - P4 Timer1 + VOUT + VSEN CSEN VCM P2 P3 PH Monitor MCP6XX, MCP6XXX CCG SR Latch VDD C2 - 100 nF - U2 Comparator MCP6291 + VREF CCM 100 nF 6 Signal Chain Design Guide RCM1 20 k RCM2 20 k Remote Sensors Remote Sensing Products All sensors in a high noise environment should be considered as remote sensors. Also, sensors not located on the same PCB as the signal conditioning circuitry are remote. Remote sensing applications typically use a differential amplifier or an instrumentation amplifier. Sensors and Applications High Precision - Low Offset Op Amps - Auto-zeroed Op Amps - Low Noise Op Amps High temperature sensors - Thermocouples for stoves, engines and process control - RTDs for ovens and process control Wheatstone Bridges - Pressure Sensors for automotive and industrial control - Strain gauges for engines Low side current monitors for motors and batteries Key Amplifier Features Differential Input Large CMR Small VOS Differential Amplifier VREF EMI - VOUT + EMI MCP6V02 MCP6V07 MCP617 MCP6V01 Thermocouple Auto-zeroed Reference Design (MCP6V01RD-TCPL) PC (Thermal Management Software) Using USB PIC18F2550 (USB) Microcontroller I2CTM Port CVREF 10-bit ADC Module VOUT2 x1 2nd Order RC Low-Pass Filter 3 VSHIFT SDA SCLK ALERT Cold Junction Compensation MCP9800 Temp Sensor MCP1541 4.1V Voltage Reference VOUT1 Difference Amplifier VREF + Type K Thermocouple Weld Bead - Connector Signal Chain Design Guide 7 Oscillator Circuits For Sensors The block diagram below shows a typical system level design, including the state-variable oscillator, PIC microcontroller and temperature sensor (used for temperature correction). RC Operational Amplifier Oscillators For Sensor Applications Op Amp or state-variable oscillators can be used to accurately measure resistive and capacitive sensors. Oscillators do not require an analog-to-digital converter and provide a sensor measurement whose conversion to digital has an accuracy limited only by the reference clock signal. State-variable oscillators are often used in sensor conditioning applications because they have a reliable start-up and a low sensitivity to stray capacitance. Absolute quartz pressure sensors and humidity sensors are examples of capacitive sensors that can use the state-variable oscillator. Also, this circuit can be used with resistive sensors, such as RTDs, to provide temperature-tofrequency conversion. Sensors and Applications Resistive Sensors RTDs Humidity Thermistors Capacitive Sensors Humidity Pressure Oil Level Related Application Notes: AN895: Oscillator Circuits for RTD Temperature Sensors AN866: Designing Operational Amplifier Oscillator Circuits for Sensor Applications Available on the Microchip web site at: www.microchip.com Oscillator Circuits for Sensors C1 R1 = RTDA R4 R2 = RTDB - - R7 + + MCP6294 2/4 MCP6234 MCP6004 VDD/2 + + VDD/2 MCP6294 1/4 MCP6234 MCP6004 VDD/2 3/4 MCP6294 MCP6234 MCP6004 VDD VOUT - MCP6541 MCP6561 Attributes: VDD R5 * Precision dual Element RTD Sensor Circuit * Reliable Oscillation Startup * Freq. (R1 x R2)1/2 + VDD/2 R6 R8 R3 - VDD/2 C4 C2 - C5 4/4 MCP6294 MCP6234 MCP6004 Oscillator Circuits for Sensors R1 = RTD Attributes: VDD C1 - A1 VOUT + MCP6541 MCP6561 R2 VDD R3 8 Signal Chain Design Guide R4 * * * * Low Cost Solution Single Comparator Circuit Square Wave Output Freq. = 1/ (1.386 x R1 x C1) Wheatstone Bridge Bridge Sensor Circuit steps (if any) should be used to increase the overall system resolution when using the MCP355X. In many situations, the MCP355X devices can be used to directly digitize the sensor output, eliminating any need for external signal conditioning circuitry. Using the absolute pressure sensor as our Wheatstone bridge example, the NPP-301 device has a typical full scale output of 60 mV when excited with a 3V battery. The pressure range for this device is 100 kPa. The MCP3551 has a output noise specification of 2.5 VRMS. The following equation is a first order approximation of the relationship between pressure in pascals (P) and altitude (h), in meters. Sensors for temperature, pressure, load or other physical excitation quantities are most often configured in a Wheatstone bridge configuration. The bridge can have anywhere from one to all four elements reacting to the physical excitation, and should be used in a ratiometeric configuration when possible, with the system reference driving both the sensor and the ADC voltage reference. By using the same reference for both the sensor excitation and ADC, the variation in the reference can be cancelled out. Furthermore, the output voltage from the bridge sensor is proportional to the excitation voltage. Therefore, the ADC that is using the external reference is more popular than the ADC that is using internal reference, for the ratiometric configuration. One example sensor from GE NovaSensor is an absolute pressure sensor, shown below, a four element varying bridge. This example uses the MCP355X family of delta sigma ADCs. When designing with the MCP355X family of 22-bit delta-sigma ADCs, the initial step should be to evaluate the sensor performance and then determine what log(P) 5 - h 15500 Using 60 mV as the full scale range and 2.5 V as the resolution, the resulting resolution from direct digitization in meters is 0.64 meters or approximately 2 feet. It should be noted that this is only used as an example for discussion; temperature effects and the error from a first order approximation must be included in final system design. Example of Wheatstone Bridge Sensor Configuration with High Resolution Delta-Sigma ADC 0.1 F 1.0 F To VDD NPP-301 2 VIN+ R2 R1 1 VREF R3 R4 8 VDD SCK MCP3551 SDO VINCS 3 VSS SPI MCU 5, 6, 7 4 Altimeter Watch V ~ [(R2+ R4) - (R1+R3)]/4R * VDD With R1 = R2 = R3 = R4 = R Signal Chain Design Guide 9 Delta-Sigma ADCs Voltage and Current Measurment Using Delta-Sigma ADCs MCP3422 Analog-to-Digital Converter (ADC) Feature Summary The MCP342X family devices are easy-to-use high precision delta sigma ADC devices from Microchip. These devices have an internal reference (2.048V) with a user programmable PGA (x1, x2, x4, x8). The ADC resolution is programmable as 12-bit, 14-bit, 16-bit or 18-bit by the user. This ADC family offers single, dual and four differential input channels. Because of its simplicity and low price, this device family can be used for various applications from simple voltage and current measurement to high precision temperature measurement. Bit Resolution 18 bits (User can select 18-, 16-, 14- or 12-bit options) Number of Differential Input Channels 2 Internal Programmable Gain Amplifier x1, x2, x4 or x8 (user option) INL Error (Typical) 10 PPM of full scale range Offset Error (Typical) 15 V Internal Reference Voltage 2.048V Output Noise (Typical) 1.5 Vrms Gain Error (Typical) 0.05% of full scale range Interface I2CTM Voltage Measurement Using MCP3421 Device R1 + + VBAT ADC ADC - VBAT - R2 MCP3421 MCP3421 MCU MCU (a) If VREF < VBAT (b) If VREF > VBAT ________ R2 VIN = ( R1 + R2 ) (VBAT) (R1 + R2) 1 VMeasured = ADC Output Codes LSB _________ _____ R2 PGA Reference Voltage LSB = ________________ 2 N -1 2.048V Reference Voltage ______ LSB of 18-bit ADC = ________________ = = 15.625 V 2 N -1 217 Current Measurement Using MCP3421 Device Current Sensor Wireless Temperature Monitoring Solution To Load 2.4 GHz Charging Current Discharging Current + Battery - ADC Heat 18-bit ADC MCP3421 + MCP3421 MRF24J40 - (Thermocouple) MCU Current = (Measured Voltage)/(Known Resistance Value of Current Sensor) Direction of current is determined by sign bit (MSB bit) of the ADC output code. 10 Signal Chain Design Guide MCP9804 Temp Sensor 1C PIC(R) MCU Delta-Sigma ADCs Temperature Measurements Using 4 Channel ADC (MCP3424) See Thermocouple Reference Design (TMPSNSRD-TCPL1) Thermocouple Sensor Isothermal Block (Cold Junction) Isothermal Block (Cold Junction) MCP3424 Delta-Sigma ADC MCP9804 SCL SDA 0.1 F 1 CH1+ CH4- 14 2 CH1- CH4+ 13 3 CH2+ CH3- 12 4 CH2- CH3+ 11 5 VSS Adr1 10 6 VDD Adr0 9 7 SDA SCL 8 MCP9804 SDA SCL VDD MCP9804 MCP9804 10 F SDA SCL Heat SCL SDA SCL SDA 5 k To MCU 5 k VDD Signal Chain Design Guide 11 Thermistor and RTD Solutions Thermistor Solutions RTD Solution Typically, thermistors require an external resistor for biasing. In addition, the inherent non-linearity of a thermistor is improved by biasing the thermistor in a resistive ladder circuit to linearize the temperature-to-voltage conversion. Typically, the thermistor voltage is directly connected to an ADC to digitize the voltage measurement. The measured voltage is converted to temperature using a lookup table. However, at hot and cold temperature extremes the nonlinearity of this approach is much greater with reduced change in voltage, which results in lower accuracy. This requires higher resolution and a more costly ADC. The solution is to use Microchip's Linear Active Thermistors, the MCP9700 and MCP9701. These are low-cost voltage output temperature sensors that replace almost any Thermistor application solutions. Unlike resistive type sensors such as Thermistors, the signal conditioning and noise immunity circuit development overhead can be avoided by using the low-cost Linear Active Thermistors. These sensors output voltage is proportional to ambient temperature with temperature coefficient of 10 mV/C and 19.5 mV/C. Unlike thermistors, these devices do not require additional computation for temperature measurement. The factory set coefficients provide linear interface to measure ambient temperatures (refer to AN1001 for sensor optimization). Resistive Temperature Detectors (RTDs) are highly accurate and repeatable temperature sensing elements. When using these sensors a robust instrumentation circuit is required and it is typically used in high performance thermal management applications such as medical instrumentation. This solution uses a high performance Delta-Sigma Analogto-Digital converter, and two resistors to measure RTD resistance ratiometrically. A 0.1C accuracy and 0.01C measurement resolution can be achieved across the RTD temperature range of -200C to +800C with a single point calibration. This solution uses a common reference voltage to bias the RTD and the ADC which provides a ratio-metric relation between the ADC resolution and the RTD temperature resolution. Only one biasing resistor, RA, is needed to set the measurement resolution ratio (shown in equation below). MCP9700 and MCP9701 Key Features SC70, TO92 packages Operating temperature range: -40C to +150C Temperature Coefficient: 10 mV/C (MCP9700) Temperature Coefficient: 19.5 mV/C (MCP9701) Low power: 6 A (typ.) RTD Resistance RRTD = RA (2 n - Code 1 - Code) Where: Code = ADC output code RA = Biasing resistor n = ADC number of bits (22 bits with sign, MCP3551) For instance, a 2V ADC reference voltage (VREF) results in a 1 V/LSb (Least Significant Bit) resolution. Setting RA = RB = 6.8 k provides 111.6 V/C temperature coefficient (PT100 RTD with 0.385/C temperature coefficient). This provides 0.008C/LSb temperature measurement resolution for the entire range of 20 to 320 or -200C to +800C. A single point calibration with a 0.1% 100 resistor provides 0.1C accuracy as shown in the figure below. This approach provides a plug-and-play solution with minimum adjustment. However, the system accuracy depends on several factors such as the RTD type, biasing circuit tolerance and stability, error due to power dissipation or self-heat, and RTD non-linear characteristics. Applications Refrigeration equipment Power supply over temperature protection General purpose temperature monitoring RTD Instrumentation Circuit Block Diagram and Output Performance (see Application Note AN1154) VDD VLDO C* C* VREF 1 F VDD PIC(R) MCU 3 SPI 0.1 RB 5% RA 1% VREF + RTD MCP3551 - *See LDO Data Sheet at: www.microchip.com/LDO 12 Signal Chain Design Guide Measured Accuracy (C) LDO 0.05 0 -0.05 -0.1 -200 0 200 400 Temperature (C) 600 800 Programmable Gain Using Digital Potentiometers Programmable Amplifier Gain Using a Digital Potentiometer Many sensors require their signal to be amplified before being converted to a digital representation. This signal gain may be done with and operational amplifier. Since all sensors will have some variation in their operational characteristics, it may be desireable to calibrate the gain of the operational amplifier to ensure an optimal output voltage range. The figure below shows two inverting amplifier with programmable gain circuits. The generic circuit (a) where R1, R2, and Pot1 can be used to tune the gain of the inverting amplifier, and the simplified circuit (b) which removes resistors R1 and R2 and just uses the digital potentiometers RAW and RBW ratio to control the gain. The simplified circuit reduces the cost and board area but there are trade-offs (for the same resistance and resolution), Using the R1 and R2 resistors allows the range of the gain to be limited and therefore each digital potentiometer step is a fine adjust within that range. While in the simplified circuit, the range is not limited and therefore each digital potentiometer step causes a larger variation in the gain. The feedback capacitor (CF) is used for circuit stability. Equation 1-1 shows how to calcultate the gain for the simplified circuit (Figure 1-1b). The gain is the ratio of the digital potentiometers wiper position on the RAB resistor ladder. As the wiper moves away from the midscale value, the gain will either become greater then one (as wiper moves towards Terminal A), or less then one (as wiper moves towards Terminal B). The device's wiper resistance (RW) is ignored for first order calculations. This is due to it being in series with the op amp input resistance and the op amp input impedence is very large. Circuit Gain Equation VOUT = - RBW x VIN RAW RBW = RAB x Wiper Code # of Resistors RAW = # of Resistors - Wiper Code x RAB # of Resistors Inverting Amplifier with Programmable Gain Circuits Generic Circuit (a) Pot1 R1 A VIN R2 B W CF - Op Amp(1) VOUT + Simplified Circuit (b) Pot1 VIN A B W CF - Op Amp(1) VOUT + Note 1: A general purpose op amp, such as the MCP6001. Signal Chain Design Guide 13 Programmable Gain Using Digital Potentiometers The table below shows a comparison of the gain between the circuits (a and b) in Figure 1-1 when using the same Digital Potentiometer (10 k, 7-bit). What you also see is that when R1 = R2 = 10 k, the circuit's gain range is between 1 and 3. While when the simplified circuit is used (effectively having R1 = R2 = 0) the circuit's gain range is between ~0 and >127. Therefore the capability for finer calibration of the circuit is capable with the generic circuit, albeit with a narrower range. Some devices have an even number of step resistors (RS) in the RAB string, while others have an odd number. In the simplified circuit, devices with an even number of RS resistors have a mid-scale wiper value that is unity gain. For devices with an odd number of RS resistors have a midscale wiper value that is near unity gain. The MCP4261 is an example of a device that has an even number of RS resistors in the RAB string, while the MCP4011 is an example of a device that has an odd number of RS resistors in the RAB string. For devices with an odd number of RS resistors in the RAB string to be able to have an exact unity gain, the device would need to be used in the generic circuit configuration (Figure 1-1), and the components would need to be selected so R1 + RAW could equal R2 + RBW. Amplifier Gain vs. Wiper Code and RW # of Taps 129 # of Resistors 128 10 k Gain Wiper Code Simplified Circuit(1) Generic Circuit(1, 2) 0 1 2 3 4 0.0 0.007874 0.015873 0.024000 0.032258 1.000000 1.007843 1.015748 1.023715 1.031746 Zero Scale . . . . . . . . . . . . 62 63 64 65 66 0.939394 0.969231 1.000000 1.031746 1.064516 1.639175 1.652850 1.666667 1.680628 1.694737 Mid Scale . . . . . . . . . . . . 124 125 126 127 128 31.000000 41.666667 63.000000 127.000000 Divide Error(3) 2.878788 2.908397 2.938462 2.968992 3.000000 Full Scale Note 1: Gain = ( (RAB / # of Resistors) * Wiper Code ) /( ( (# of Resistors - Wiper Code) / # of Resistors) * RAB) 2: Uses R1 = R2 = 10 k. 3: Theoretical calculations. At full scale in the simplified circuit a divide by 0 error results. 14 Signal Chain Design Guide Comment Sensor Circuit Calibration using a DAC Setting the DC Set Point for Sensor Circuit A common DAC application is digitally controlling the set point and/or calibration of parameters in a signal chain. The figure below shows controlling the DC set point of a light detector sensor using the MCP4728 12-bit quad DAC device. The DAC provides 4096 output steps. If G = 1 and internal reference voltage options are selected, then the internal 2.048 VREF would produce 500 V of resolution. If G = 2 is selected, the internal 2.048 VREF would produce 1 mV of resolution. If a smaller output step size is desired, the output range would need to be reduced. So, using gain of 1 is a better choice than using gain of 2 configuration option for smaller step size, but its full-scale range is one half of that of the gain of 2. Using a voltage divider at the DAC output is another method for obtaining a smaller step size. Setting the DC Set Point Light VDD Comparator 1 RSENSE - R1 VTRIP1 Light + R2 MCP6544(1/4) 0.1 F VDD Comparator 2 VDD RSENSE R1 R3 1 10 2 9 VOUT D SDA 3 8 VOUT C LDAC 4 7 VOUT B RDY/BSY 5 6 VOUT A MCP4728 Quad DAC VSS Light VDD Analog Outputs Comparator 3 RSENSE VOUT = VREF x Dn GX 4096 R2 VTRIP = VOUT x R1 + R2 Where Dn = Input Code (0 to 4095) GX = Gain Selection (x1 or x2) R1 VTRIP3 R2 Light MCP6544(3/4) 0.1 F VDD Comparator 4 RSENSE R1 VTRIP4 R2 0.1 F + To MCU - R6 VDD SCL MCP6544(2/4) 0.1 F + R5 R2 - R4 VTRIP2 + 10 F - 0.1 F MCP6544(4/4) Signal Chain Design Guide 15 MindiTM Amplifier Designer & Simulator MindiTM Amplifier Designer & Simulator MindiTM Active Filter Designer & Simulator The Mindi Active Filter Designer & Simulator is an Application Circuit within the Mindi Circuit Designer & Simulator that provides full schematic diagrams of the active filter circuit with recommended component values and displays the signal responses in frequency and time domains. The Mindi Active Filter Designer & Simulator allows the design of low-pass filters up to an 8th order filter with Chebychev, Bessel or Butterworth approximations from frequencies of 0.1 Hz to 1 MHz. It also can be used to design band-pass and high-pass filters with Chebychev and Butterworth approximations. The circuit topologies supported by the tool are the Sallen Key and Multiple Feedback (MFB). The low-pass filters can use either the Sallen Key or MFB, the band-pass filter is available with the MFB and the high-pass filter uses the Sallen Key. The Mindi Amplifier Designer & Simulator is an Application Circuit that generates full schematic diagrams of an amplifier circuit with recommended component values and displays the signal responses in frequency and time domains. This application circuit allows the following designs: Inverting Amplifier Non-inverting Amplifier Voltage Follower Difference Amplifier Inverting Summing Amplifier Inverting Comparator Inverting Differentiator Inverting Integrator Once the amplifier characteristics have been identified, the Mindi Amplifier Designer & Simulator can generate and simulate the schematic of the amplifier circuit. For maximum design flexibility, changes in resistor and capacitor values can be implemented to fit the demands of the application. The tool also generates a Design Summary of the designed amplifier, including Design Requirements, Application Schematic, Result Plot and Bill of Materials (BOM). Users can directly download the schematic, BOM and Mindi offline version. 16 Signal Chain Design Guide Users can select a flat pass-band or sharp transition from pass-band to stop-band. Other options, such as minimum ripple factor, sharp transition and linear phase delays are available. Once the filter characteristics have been identified, the Mindi Active Filter Designer & Simulator can generate and simulate the schematic of filter circuit. For maximum design flexibility, changes in resistor and capacitor values can be implemented to fit the demands of the application. The tool will recalculate all values to meet the desired response, allowing real-world values to be substituted or changed as part of the design process. The tool also generates a Bill of Materials (BOM) of the designed filter. Both of these tools are available on the Microchip web site (www.microchip.com) under "Design & Simulation Tools" or on the Mindi home page (http://www.microchip.com/mindi). The op amps and evaluation boards can also be ordered from the Microchip web site. Development Tools These following development boards support the the development of signal chain applications. These product families may have other demonstration and evaluation boards that may also be useful. For more information visit www.microchip.com/analogtools ADCs MCP3421 Battery Fuel Gauge Demo (MCP3421DM-BFG) The MCP3421 Battery Fuel Gauge Demo Board demonstrates how to measure the battery voltage and discharging current using the MCP3421. The MCU algorithm calculates the battery fuel being used. This demo board is shipped with 1.5V AAA non-rechargeable battery. The board can also charge a single-cell 4.2V Li-Ion battery. MCP3551 Tiny Application (Pressure) Sensor Demo DACs MCP4725 PICtailTM Plus Daughter Board (MCP4725DM-PTPLS) This daughter board demonstrates the MCP4725 (12 bit DAC with non-volatile memory) features using the Explorer 16 Development Board and the PICkit Serial Analyzer. MCP4725 SOT-23-6 Evaluation Board (MCP4725EV) The MCP4725 SOT-23-6 Evaluation Board is a quick and easy evaluation tool for the MCP4725 12-bit DAC device. It works with Microchip's popular PICkitTM Serial Analyzer or independently with the customer's applications board. The PICkit Serial Analyzer is sold separately. (MCP355XDM-TAS) This 1 x 1 board is designed to demonstrate the performance of the MCP3550/1/3 devices in a simple low-cost application. The circuit uses a ratiometric sensor configuration and uses the system power supply as the voltage reference. The extreme common mode rejection capability of the MCP355X devices, along with their excellent normal mode power supply rejection at 50 and 60 Hz, allows for excellent system performance. MCP4728 Evaluation Board (MCP4728EV) MCP3551 Sensor Application Developer's Board (MCP6031DM-PTPLS) The MCP6031 Photodiode PICtail Plus Demo Board demonstrates how to use a transimpedance amplifier, which consists of MCP6031 high precision op amp and external resistors, to convert photo-current to voltage. (MCP355XDV-MS1) The MCP355X Sensor Developer's Board allows for easy system design of high resolution systems such as weigh scale, temperature sensing, or other small signal systems requiring precise signal conditioning circuits. The reference design includes LCD display firmware that performs all the necessary functions including ADC sampling, USB communication for PC data analysis, LCD display output, zero cancellation, full scale calibration, and units display in gram (g), kilogram (kg) or ADC output units. MCP3901 ADC Evaluation Board for 16-bit MCUs (MCP3901EV-MCU16) The MCP3901 ADC Evaluation Board for 16-bit MCUs system provides the ability to evaluate the performance of the MCP3901 dual channel ADC. It also provides a development platform for 16-bit PIC based applications, using existing 100-pin PIM systems. The MCP4728 Evaluation Board is a tool for quick and easy evaluation of the MCP4728 4-channel 12-bit DAC device. It contains the MCP4728 device and connection pins for the Microchip's popular PICkitTM Serial Analyzer. The PICkit Serial Analyzer is sold separately. Op Amps MCP6031 Photodiode PICtailTM Plus Demo Board MCP651 Input Offset Evaluation Board (MCP651EV-VOS) The MCP651 Input Offset Evaluation Board is intended to provide a simple means to measure the MCP651 Input Offset Evaluation Board op amp's input offset voltage under a variety of operating conditions. The measured input offset voltage (VOST) includes the input offset voltage specified in the data sheet (VOS) plus changes due to: power supply voltage (PSRR), common mode voltage (CMRR), output voltage (AOL), input offset voltage drift over temperature (VOS/TA) and 1/f noise. Signal Chain Design Guide 17 Development Tools MCP6V01 Input Offset Demo Board Thermocouple Reference Design (TMPSNSRD-TCPL1) (MCP6V01DM-VOS) The MCP6V01 Input Offset Demo Board is intended to provide a simple means to measure the MCP6V01/2/3 op amps input offset voltage (VOS) under a variety of bias conditions. This VOS includes the specified input offset voltage value found in the data sheet plus changes due to power supply voltage (PSRR), common mode voltage (CMRR), output voltage (AOL) and temperature (IVOS/ITA). The Thermocouple Reference Design demonstrates how to instrument a Thermocouple and accurately sense temperature over the entire Thermocouple measurement range. This solution uses the MCP3421 18-bit Analog-to-Digital Converter (ADC) to measure voltage across the Thermocouple. MCP661 Line Driver Demo Board (MCP661DM-LD) This demo board uses the MCP661 in a very basic application for high speed op amps; a 50 line (coax) driver. The board offers a 30 MHz solution, high speed PCB layout techniques and a means to test AC response, step response and distortion. Both the input and the output are connected to lab equipment with 50 BNC cables. There are 50 terminating resistors and transmission lines on the board. The op amp is set to a gain of 2V/V to overcome the loss at its output caused by the 50 resistor at that point. Connecting lab supplies to the board is simple; there are three surface mount test points provided for this purpose. MCP6V01 Thermocouple Auto-Zero Reference Design (MCP6V01RD-TCPL) The MCP6V01 Thermocouple Auto-Zeroed Reference Design demonstrates how to use a difference amplifier system to measure electromotive force (EMF) voltage at the cold junction of thermocouple in order to accurately measure temperature at the hot junction. This can be done by using the MCP6V01 auto-zeroed op amp because of its ultra low offset voltage (VOS) and high common mode rejection ratio (CMRR). MCP6XXX Active Filter Demo (MCP6XXXDM-FLTR) This kit supports MindiTM Active Filter Designer & Simulator and active filters designed by FilterLab(R) V2.0. These filters are all pole and are built by cascading first and second order sections. Amplifier Evaluation Board 1 (MCP6XXXEV-AMP1) The MCP6XXX Amplifier Evaluation Board 1 is designed to support inverting/ non-inverting amplifiers, voltage followers, inverting/non-inverting comparators, inverting/non-inverting differentiators. Amplifier Evaluation Board 2 (MCP6XXXEV-AMP2) The MCP6XXX Amplifier Evaluation Board 2 supports inverting summing amplifiers and non-inverting summing amplifiers. Amplifier Evaluation Board 3 (MCP6XXXEV-AMP3) The MCP6XXX Amplifier Evaluation Board 3 is designed to support the difference amplifier circuits which are generated by the MindiTM Amplifier Designer. Amplifier Evaluation Board 4 (MCP6XXXEV-AMP4) The MCP6XXX Amplifier Evaluation Board 4 is designed to support the inverting integrator circuit. 18 Signal Chain Design Guide Temp Sensors MCP9800 Temp Sensor Demo Board (MCP9800DM-TS1) The MCP9800 Temperature Sensor Demo Board demonstrates the sensor's features. Users can connect the demo board to a PC with USB interface and evaluate the sensor performance. The 7-Segment LED displays temperature in degrees Celsius or degrees Fahrenheit; the temperature alert feature can be set by the users using an on board potentiometer. An alert LED is used to indicate an over temperature condition. In addition, temperature can be datalogged using the Microchip Thermal Management Software Graphical User Interface (GUI). The sensor registers can also be programmed using the GUI. MCP6S26 PT100 RTD Evaluation Board (TMPSNS-RTD1) The PT100 RTD Evaluation Board demonstrates how to bias a Resistive Temperature Detector (RTD) and accurately measure temperature. Up to two RTDs can be connected. The RTDs are biased using constant current source and the output voltage is scaled using a difference amplifier. In addition to the difference amplifier, a multiple input channel Programmable Gain Amplifier (PGA) MCP6S26 is used to digitally switch between RTDs and increase the scale up to 32 times. Development Tools RTD Reference Design Board (TMPSNSRD-RTD2) The RTD Reference Design demonstrates how to implement Resistive Temperature Detector (RTD) and accurately measure temperature. This solution uses the MCP3551 22-bit Analog-to-Digital Converter (ADC) to measure voltage across the RTD. The ADC and the RTD are referenced using an onboard reference voltage and the ADC inputs are directly connected to the RTD terminals. This provides a ratio metric temperature measurement. The solution uses a current limiting resistor to bias the RTD. It provides a reliable and accurate RTD instrumentation without the need for extensive circuit compensation and calibration routines. In addition, the this reference design includes a silicon temperature sensor, MCP9804. This sensor is used for comparison only, it is not needed to instrument an RTD. The MCP3551 and MCP9804 outputs are read using a USB PIC microcontroller. This controller is also connected to a PC using USB interface. The thermal management software is used plot the RTD temperature data in stripchart format. Thermocouple Reference Design Board (TMPSNSRD-TCPL1) The Thermocouple Reference Design demonstrates how to implement a thermocouple and accurately sense temperature over the entire thermocouple measurement range. This solution uses the MCP3421 18-bit Analogto-Digital Converter (ADC) to measure voltage across the Thermocouple. The ADC has an internal 2.048V reference voltage and a Programmable Gain Amplifier with 1, 2, 4, 8 V/V. At a Gain of 8 V/V the PGA effectively adds 3 LSb to the ADC. This increases the ADC resolution to 21-bit or 2 V/LSb. Therefore, the Thermocouple EMF voltage is measured with 2 V resolution. For K-type thermocouple, measurement system provides a 0.05C resolution. The cold-junction compensation is done using a 1C accurate 0.0625C resolution silicon temperature sensor, the MCP9804. This solution provides a reliable and accurate Thermocouple instrumentation without the need for extensive circuit compensation and calibration routines. Signal Chain Design Guide 19 Related Support Material The following literature is available on the Microchip web site: www.microchip.com/appnotes. There are additional application notes that may be useful. Sensor Conditioning Circuits Overview AN866: Designing Operational Amplifier Oscillator Circuits For Sensor Applications Operational amplifier (op amp) oscillators can be used to accurately measure resistive and capacitive sensors. Oscillator design can be simplified by using the procedure discussed in this application note. The derivation of the design equations provides a method to select the passive components and determine the influence of each component on the frequency of oscillation. The procedure will be demonstrated by analyzing two state-variable RC op-amp oscillator circuits. AN895: Oscillator Circuits for RTD Temperature Sensors This application note shows how to design a temperature sensor oscillator circuit using Microchip's low-cost MCP6001 operational amplifier (op amp) and the MCP6541 comparator. Oscillator circuits can be used to provide an accurate temperature measurement with a Resistive Temperature Detector (RTD) sensor. Oscillators provide a frequency output that is proportional to temperature and are easily integrated into a microcontroller system. AN990: Analog Sensor Conditioning Circuits - An Overview Analog sensors produce a change in an electrical property to indicate a change in its environment. this change in electrical property needs to be conditioned by an analog circuit before conversion to digital. Further processing occurs in the digital domain but is not addressed in this application note. Delta-Sigma ADCs AN1007: Designing with the MCP3551 Delta-Sigma ADC The MCP3551 delta-sigma ADC is a high-resolution converter. This application note discusses various design techniques to follow when using this device. Typical application circuits are discussed first, followed by a section on noise analysis. AN1030: Weigh Scale Applications for the MCP3551 This application note focusses specifically on load cells, a type of strain gauge that is typically used for measuring weight. Even more specifically, the focus is on fully active, temperature compensated load cells whose change in differential output voltage with a rated load is 2 mV to 4 mV per volt of excitation (the excitation voltage being the difference between the +Input and the -Input terminals of the load cell). AN1156: Battery Fuel Measurement Using Delta-Sigma ADC Devices This application note reviews the battery fuel measurement using the MCU and ADC devices. Developing battery fuel measurement in this manner provides flexible solutions and enables economic management. DS21841: Analog-to-Digital Converter Design Guide 20 Signal Chain Design Guide SAR ADCs AN246: Driving the Analog Inputs of a SAR A/D Converter This application note delves into the issues surrounding the SAR converter's input and conversion nuances to insure that the converter is handled properly from the beginning of the design phase. AN688: Layout Tips for 12-Bit A/D Converter Application This application note provides basic 12-bit layout guidelines, ending with a review of issues to be aware of. Examples of good layout and bad layout implementations are presented throughout. AN693: Understanding A/D Converter Performance Specifications This application note describes the specifications used to quantify the performance of A/D converters and give the reader a better understanding of the significance of those specifications in an application. AN842: Differential ADC Biasing Techniques, Tips and Tricks True differential converters can offer many advantages over single-ended input A/D Converters (ADC). In addition to their common mode rejection ability, these converters can also be used to overcome many DC biasing limitations of common signal conditioning circuits. AN845: Communicating With The MCP3221 Using PIC Microcontrollers This application note will cover communications between the MCP3221 12-bit A/D Converter and a PIC microcontroller. The code supplied with this application note is written as relocatable assembly code. Passive Keyless Entry (PKE) TB090: MCP2030 Three-Channel Analog Front-End Device Overview This tech brief summarizes the technical features of the MCP2030 and describes how the three channel stand-alone analog front-end device can be used for various bidirectional communication applications. AN1024: PKE System Design Using the PIC16F639 This application note described how to make hands-free reliable passive keyless entry applications using the PIC16F639 - a dual die solution device that includes both MCP2030 and PIC16F636. Utility Metering Refer to DS01008: Utility Metering Solutions Related Support Material Digital Potentiometers AN691: Optimizing the Digital Potentiometer in Precision Circuits In this application note, circuit ideas are presented that use the necessary design techniques to mitigate errors, consequently optimizing the performance of the digital potentiometer. AN692: Using a Digital Potentiometer to Optimize a Precision Single Supply Photo Detect This application note shows how the adjustability of the digital potentiometer can be used to an advantage in photosensing circuits. AN1080: Understanding Digital Potentiometer Resistance Variations This application note discusses how process, voltage and temperature effect the resistor network's characteristics, specifications and techniques to improve system performance. Op Amps AN679: Temperature Sensing Technologies Covers the most popular temperature sensor technologies and helps determine the most appropriate sensor for an application. AN681: Reading and Using Fast Fourier Transformation (FFT) Discusses the use of frequency analysis (FFTs), time analysis and DC analysis techniques. It emphasizes Analogto-Digital converter applications. AN684: Single Supply Temperature Sensing with Thermocouples Focuses on thermocouple circuit solutions. It builds from signal conditioning components to complete application circuits. AN695: Interfacing Pressure Sensors to Microchip's Analog Peripherals Shows how to condition a Wheatstone bridge sensor using simple circuits. A piezoresistive pressure sensor application is used to illustrate the theory. AN699: Anti-Aliasing, Analog Filters for Data Acquisition Systems A tutorial on active analog filters and their most common applications. AN722: Operational Amplifier Topologies and DC Specifications Defines op amp DC specifications found in a data sheet. It shows where these specifications are critical in application circuits. AN723: Operational Amplifier AC Specifications and Applications Defines op amp AC specifications found in a data sheet. It shows where these specifications are critical in application circuits. AN866: Designing Operational Amplifier Oscillator Circuits For Sensor Applications Gives simple design procedures for op amp oscillators. These circuits are used to accurately measure resistive and capacitive sensors. AN884: Driving Capacitive Loads With Op Amps Explains why all op amps tend to have problems driving large capacitive loads. A simple, one resistor compensation scheme is given that gives much better performance. AN951: Amplifying High-Impedance Sensors - Photodiode Example Shows how to condition the current out of a high-impedance sensor. A photodiode detector illustrates the theory. AN990: Analog Sensor Conditioning Circuits - An Overview Gives an overview of the many sensor types, applications and conditioning circuits. AN1014: Measuring Small Changes in Capacitive Sensors This application note shows a switched capacitor circuit that uses a PIC microcontroller, and minimal external passive components, to measure small changes in capacitance. The values are very repeatable under constant environmental conditions. AN1016: Detecting Small Capacitive Sensors Using the MCP6291 and PIC16F690 Devices The circuit discussed here uses an op amp and a microcontroller to implement a dual slope integrator and timer. It gives accurate results, and is appropriate for small capacitive sensors, such as capacitive humidity sensors. AN1177: Op Amp Precision Design: DC Errors This application note covers the essential background information and design theory needed to design a precision DC circuit using op amps. AN1228: Op Amp Precision Design: Random Noise This application note covers the essential background information and design theory needed to design low noise, precision op amp circuits. The focus is on simple, results oriented methods and approximations useful for circuits with a low-pass response. AN1258: Op Amp Precision Design: PCB Layout Techniques This application note covers Printed Circuit Board (PCB) effects encountered in high (DC) precision op amp circuits. It provides techniques for improving the performance, giving more flexibility in solving a given design problem. It demonstrates one important factor necessary to convert a good schematic into a working precision design. AN1297: Microchip's Op Amp SPICE Macro Models This application note covers the function and use of Microchip's op amp SPICE macro models. It does not explain how to use the circuit simulator but will give the user a better understanding how the model behaves and tips on convergence issues. Signal Chain Design Guide 21 Related Support Material Programmable Gain Amplifier (PGA) AN248: Interfacing MCP6S2X PGAs to PIC Microcontrollers This application note shows how to program the six channel MCP6S26 PGA gains, channels and shutdown registers using the PIC16C505 microcontroller. AN865: Sensing Light with a Programmable Gain Amplifier This application notes discusses how Microchip's Programmable Gain Amplifiers (PGAs) can be effectively used in position photo sensing applications minus the headaches of amplifier stability. AN897: Thermistor Temperature Sensing with MCP6SX2 PGAs Shows how to use a Programmable Gain Amplifier (PGA) to linearize the response of a thermistor, and to achieve a wider temperature measurement range. Temperature Sensing AN929: Temperature Measurement Circuits for Embedded Applications This application note shows how to select a temperature sensor and conditioning circuit to maximize the measurement accuracy and simplify the interface to the microcontroller. AN981: Interfacing a MCP9700 Analog Temperature Sensor to a PIC Microcontroller Analog output silicon temperature sensors offer an easyto-use alternative to traditional temperature sensors, such as thermistors. The MCP9700 offers many system-level advantages, including the integration of the temperature sensor and signal-conditioning circuitry on a single chip. Analog output sensors are especially suited for embedded systems due to their linear output. This application note will discuss system integration, firmware implementation and PCB layout techniques for using the MCP9700 in an embedded system. AN988: Interfacing a MCP9800 I2CTM Digital Temperature Sensor to a PIC Microcontroller This application note will discuss system integration, firmware implementation and PCB layout techniques for using the MCP9800 in an embedded system. AN1001: IC Temperature Sensor Accuracy Compensation with a PIC Microcontroller This application note derives an equation that describes the sensor's typical non-linear characteristics, which can be used to compensate for the sensor's accuracy error over the specified operating temperature range. 22 Signal Chain Design Guide AN1154: Precision RTD Instrumentation for Temperature Sensing Precision RTD (Resistive Temperature Detector) instrumentation is key for high performance thermal management applications. This application note shows how to use a high resolution Delta-Sigma Analog-toDigital converter, and two resistors to measure RTD resistance ratiometrically. A 0.1C accuracy and 0.01C measurement resolution can be achieved across the RTD temperature range of -200C to +800C with a single point calibration. AN1306: Thermocouple Circuit Using MCP6V01 and PIC18F2550 This application note shows how to use a difference amplifier system to measure electromotive force (EMF) voltage at the cold junction of thermocouple in order to accurately measure temperature at the hot junction. This can be done by using the MCP6V01 auto-zeroed op amp because of its extremely low input offset voltage (VOS) and very high common mode rejection ratio (CMRR). The microcontroller PIC18F2550 used in this circuit has internal comparator voltage reference (CVREF). This solution minimizes cost by using resources internal to the PIC18F2550 to achieve reasonable resolution without an external ADC. LINEAR LINEAR - Op Amps Device MCP6031/2/3/4 # per Package GBWP (kHz) Typ. IQ (A/amp.) Typ. VOS (V) Max. Supply Voltage (V) Temperature Range (C) Railto-Rail I/O 1,2,1,4 10 1 150 1.8 to 5.5 -40 to +125 I/O MCP6041/2/3/4 1,2,1,4 14 1 3,000 1.4 to 6.0 -40 to +85, -40 to +125 MCP6141/2/3/4 1,2,1,4 100 1 3,000 1.4 to 6.0 -40 to +85, -40 to +125 Features Packages Featured Demo Board Op Amp Category Low Power Mode on MCP6033 SOIC, MSOP, TSSOP, DFN, SOT-23 MCP6031DM-PCTL, SOIC8EV, SOIC14EV Low Offset, Low Power I/O Low Power Mode on MCP6043 PDIP, SOIC, MSOP, TSSOP, SOT-23 SOIC8EV, SOIC14EV General Purpose, Low Power I/O GMIN = 10, Low Power Mode on MCP6143 PDIP, SOIC, MSOP, TSSOP, SOT-23 SOIC8EV, SOIC14EV General Purpose, Low Power SOIC8EV, SOIC14EV Low Offset MCP606/7/8/9 1,2,1,4 155 25 250 2.5 to 6.0 -40 to +85 O Low Power Mode on MCP608 PDIP, SOIC, TSSOP, DFN, SOT-23 MCP616/7/8/9 1,2,1,4 190 25 150 2.3 to 5.5 -40 to +85 O Low Power Mode on MCP618 PDIP, SOIC, TSSOP SOIC8EV, SOIC14EV Low Offset VSUPEV2, SOIC8EV, SOIC14EV General Purpose MCP6231/1R/1U/2/4 MCP6051/2/4 MCP6241/1R/1U/2/4 MCP6061/2/4 MCP6001/1R/1U/2/4 MCP6071/2/4 MCP6271/1R/2/3/4/5 MCP601/1R/2/3/4 MCP6286 MCP6281/1R/2/3/4/5 MCP6021/1R/2/3/4 1,1,1,2,4 300 30 5,000 1.8 to 6.0 -40 to +125 I/O - PDIP, SOIC, MSOP, TSSOP, DFN, SOT-23, SC-70 1,2,4 385 45 150 1.8 to 6.0 -40 to +125 I/O - SOIC, TSSOP, TDFN SOIC8EV, SOIC14EV Low Offset VSUPEV2, SOIC8EV, SOIC14EV General Purpose 1,1,1,2,4 550 70 5,000 1.8 to 5.5 -40 to +125 I/O - PDIP, SOIC, MSOP, TSSOP, DFN, SOT-23, SC-70 1,2,4 730 90 150 1.8 to 6.0 -40 to +125 I/O - SOIC, TSSOP, TDFN SOIC8EV, SOIC14EV Low Offset I/O - PDIP, SOIC, MSOP, TSSOP, SOT-23, SC-70 MCP6SX2DM-PICTLPD, SOIC8EV, SOIC14EV General Purpose I/O - SOIC, TSSOP, TDFN SOIC8EV, SOIC14EV Low Offset I/O Low Power Mode on MCP6273, Cascaded Gain with MCP6275 PDIP, SOIC, MSOP, TSSOP, SOT-23 MCP6XXXDM-FLTR, SOIC8EV, SOIC14EV General Purpose 1,1,1,2,4 1,000 170 4,500 1.8 to 6.0 -40 to +85, -40 to +125 1,2,4 1,200 170 150 1.8 to 6.0 -40 to +125 1,1,2,1,4,2 2,000 240 3,000 2.0 to 6.0 -40 to +125 1,1,2,1,4 2,800 325 2,000 2.7 to 6.0 -40 to +85, -40 to +125 O Low Power Mode on MCP603 PDIP, SOIC, TSSOP, SOT-23 SOIC8EV, SOIC14EV General Purpose 1 3,500 720 1,500 2.2 to 5.5 -40 to +125 O Low Noise SOT-23 VSUPEV2 Low Noise 1,1,2,1,4,2 5,000 570 3,000 2.2 to 6.0 -40 to +125 I/O Low Power Mode on MCP6283, Cascaded Gain with MCP6285 PDIP, SOIC, MSOP, TSSOP, SOT-23 VSUPEV2, SOIC8EV, SOIC14EV General Purpose 1,1,2,1,4 10,000 1,350 500, 250 2.5 to 5.5 -40 to +85, -40 to +125 I/O Low Power Mode on MCP6023 PDIP, SOIC, MSOP, TSSOP, SOT-23 MCP6XXXEV-AMP1, SOIC8EV, SOIC14EV Low Offset PDIP, SOIC, MSOP, TSSOP, SOT-23 PIC16F690DM-PCTLHS, SOIC8EV, SOIC14EV General Purpose 1,1,2,1,4,2 10,000 1,300 3,000 2.4 to 6.0 -40 to +125 I/O Low Power Mode on MCP6293, Cascaded Gain with MCP6295 1,2,2 20,000 3,600 200 2.5 to 5.5 -40 to +125 O mCal (offset correction, low power mode) SOIC, MSOP, DFN MCP651EV-VOS High Speed, High Output Drive, Low Offset 1,2,1,2 24,000 3,600 8,000 2.5 to 5.5 -40 to +125 O Low Power Mode on MCP633/5 SOIC, MSOP, DFN MCP651EV-VOS High Speed, High Output Drive 1,2,2 50,000 9,000 200 2.5 to 5.5 -40 to +125 O mCal (offset correction, low power mode) SOIC, MSOP, DFN MCP651EV-VOS High Speed, High Output Drive, Low Offset 1,2,1,2 60,000 9,000 8,000 2.5 to 5.5 -40 to +125 O Low Power Mode on MCP663/5 SOIC, MSOP, DFN MCP661DM-LD High Speed, High Output Drive # per Package GBWP (kHz) Typ. IQ (A/amp.) Typ. VOS (V) Max. Supply Voltage (V) Temperature Range (C) Railto-Rail I/O MCP6V01/2/3 1,2,1 1,300 400 2 1.8 to 5.5 -40 to +125 I/O Low Power Mode on MCP6V03 SOIC, DFN, TDFN MCP6V01DM-VOS, MCP6V01RD-TCPL Auto-zeroed MCP6V06/7/8 1,2,1 1,300 400 3 1.8 to 5.5 -40 to +125 I/O Low Power Mode on MCP6V08 SOIC, DFN, TDFN MCP6V01DM-VOS, MCP6V01RD-TCPL Auto-zeroed MCP6291/1R/2/3/4/5 MCP621 MCP631/2/3/5 MCP651/2/5 MCP661/2/3/5 LINEAR - Op Amps Auto-Zero Device Features Packages Featured Demo Board Op Amp Category Signal Chain Design Guide 23 LINEAR - Comparators # per Package VREF (V) Typical Propagation Delay (s) IQ Typical (A) Vos Max (mV) Operating Voltage (V) Temperature Range (C) MCP6541 1 - 4 1 5 1.6 to 5.5 -40 to +125 Push-Pull, Rail-to-Rail Input/Output MCP6542 2 - 4 1 5 1.6 to 5.5 -40 to +125 Push-Pull, Rail-to-Rail Input/Output 8-pin PDIP, 8-pin SOIC, 8-pin MSOP MCP6543 1 - 4 1 5 1.6 to 5.5 -40 to +125 Push-Pull, Rail-to-Rail Input/Output, Chip Select 8-pin PDIP, 8-pin SOIC, 8-pin MSOP MCP6544 4 - 4 1 5 1.6 to 5.5 -40 to +125 Push-Pull, Rail-to-Rail Input/Output 14-pin PDIP, 14-pin SOIC, 14-pin TSSOP MCP6546 1 - 4 1 5 1.6 to 5.5 -40 to +125 Open-drain, 9V, Rail-to-Rail Input/Output 5-pin SOT-23(S,R,U), 5-pin SC-70(S,U), 8-pin PDIP, 8-pin SOIC, 8-pin MSOP MCP6547 2 - 4 1 5 1.6 to 5.5 -40 to +125 Open-drain, 9V, Rail-to-Rail Input/Output 8-pin PDIP, 8-pin SOIC, 8-pin MSOP MCP6548 1 - 4 1 5 1.6 to 5.5 -40 to +125 Open-drain, 9V, Rail-to-Rail Input/Output, Chip Select 8-pin PDIP, 8-pin SOIC, 8-pin MSOP MCP6549 4 - 4 1 5 1.6 to 5.5 -40 to +125 Open-drain, 9V, Rail-to-Rail Input/Output 14-pin PDIP, 14-pin SOIC, 14-pin TSSOP MCP6561 1 - 0.047 100 10 1.8 to 5.5 -40 to +125 Push-Pull, Rail-to-Rail Input/Output 5-pin SOT-23(S,R,U), 5-pin SC-70(S) MCP6562 2 - 0.047 100 10 1.8 to 5.5 -40 to +125 Push-Pull, Rail-to-Rail Input/Output 8-pin SOIC, 8-pin MSOP MCP6564 4 - 0.047 100 10 1.8 to 5.5 -40 to +125 Push-Pull, Rail-to-Rail Input/Output 14-pin SOIC, 14-pin TSSOP MCP6566 1 - 0.047 100 10 1.8 to 5.5 -40 to +125 Open-Drain, Rail-to-Rail Input/Output 5-pin SOT-23(S,R,U), 5-pin SC-70(S) MCP6567 2 - 0.047 100 10 1.8 to 5.5 -40 to +125 Open-Drain, Rail-to-Rail Input/Output 8-pin SOIC, 8-pin MSOP MCP6569 4 - 0.047 100 10 1.8 to 5.5 -40 to +125 Open-Drain, Rail-to-Rail Input/Output 14-pin SOIC, 14-pin TSSOP Device Features Packages 5-pin SOT-23(S,R,U), 5-pin SC-70(S,U), 8-pin PDIP, 8-pin SOIC, 8-pin MSOP Legend: S = Standard Pinout; R = Reverse Pinout; U = Alternative Pinout LINEAR - Programmable Gain Amplifiers (PGA) Device MCP6S21/2/6/8 MCP6S912,3 Channels -3 dB BW (MHz) Typ. IQ (A) Max. VOS (V) Max. Operating Voltage (V) Temperature Range (C) 1, 2, 6, 8 2 to 12 1.1 275 2.5 to 5.5 -40 to +85 SPI, 8 Gain Steps, Software Shutdown Features PDIP, SOIC, MSOP, TSSOP Packages 1, 2, 2 1 to 18 1.0 4000 2.5 to 5.5 -40 to +125 SPI, 8 Gain Steps, Software Shutdown, VREF PDIP, SOIC, MSOP MIXED SIGNAL MIXED SIGNAL - Delta-Sigma A/D Converters Resolution (bits) Max.Sample Rate (samples/sec) # of Input Channels Interface Supply Voltage (V) Typical Supply Current (A) Typical INL (ppm) Temperature Range (C) MCP3421 18 3.75 1 Diff I2CTM 2.7 to 5.5 145 (continuous) 39 (one shot) 10 -40 to +85 PGA: 1, 2, 4 or 8 Internal voltage reference SOT-23-6 MCP3421EV MCP3422 18 3.75 2 Diff ICTM 2.7 to 5.5 145 10 -40 to +85 PGA: 1, 2, 4, or 8 Internal voltage reference SOIC-8, MSOP-8, DFN-8 MCP3422EV, MCP3421DM-BFG MCP3423 18 3.75 2 Diff ICTM 2.7 to 5.5 145 10 -40 to +85 PGA: 1, 2, 4, or 8 Internal voltage reference MSOP-10, DFN-10 MCP3423EV MCP3424 18 3.75 4 Diff ICTM 2.7 to 5.5 145 10 -40 to +85 PGA: 1, 2, 4, or 8 Internal voltage reference SOIC-14, TSSOP-14 MCP3424EV MCP3425 16 15 1 Diff ICTM 2.7 to 5.5 155 10 -40 to +85 PGA: 1, 2, 4, or 8 Internal voltage reference SOT-23-6 MCP3425EV, MCP3421DM-BFG MCP3426 16 15 2 Diff ICTM 2.7 to 5.5 145 10 -40 to +85 PGA: 1, 2, 4, or 8 Internal voltage reference SOIC-8, MSOP-8, DFN-8 - MCP3427 16 15 2 Diff ICTM 2.7 to 5.5 145 10 -40 to +85 PGA: 1, 2, 4, or 8 Internal voltage reference MSOP-10, DFN-10 - MCP3428 16 15 4 Diff ICTM 2.7 to 5.5 145 10 -40 to +85 PGA: 1, 2, 4, or 8 Internal voltage reference SOIC-14, TSSOP-14 - Device Features Packages Featured Demo Board Signal Chain Design Guide 24 MIXED SIGNAL - Delta-Sigma A/D Converters (Continued) Resolution (bits) Max.Sample Rate (samples/sec) # of Input Channels Interface Supply Voltage (V) Typical Supply Current (A) Typical INL (ppm) Temperature Range (C) MCP3550-50 22 13 1 Diff SPI 2.7 to 5.5 120 2 -40 to +85 50 Hz noise rejection > 120 dB SOIC-8, MSOP-8 MCP3551DM-PCTL MCP3550-60 22 15 1 Diff SPI 2.7 to 5.5 140 2 -40 to +85 60 Hz noise rejection > 120 dB SOIC-8, MSOP-8 MCP3551DM-PCTL MCP3551 22 14 1 Diff SPI 2.7 to 5.5 120 2 -40 to +85 Simultaneous 50/60 Hz rejection SOIC-8, MSOP-8 MCP3551DM-PCTL MCP3553 20 60 1 Diff SPI 2.7 to 5.5 140 2 -40 to +85 - SOIC-8, MSOP-8 MCP3551DM-PCTL MCP3901 16 64000 2 Diff SPI 4.5 to 5.5 2050 15 -40 to +85 Two ADC Cores, 16/24 bits, High Sample Speed (64 ksps), PGA: 1, 2, 4, 8, 16 or 32 SSOP-20, QFN-20 MCP3901EV-MCU16 Device Features Packages Featured Demo Board MIXED SIGNAL - Successive Approximation Register (SAR) A/D Converters Resolution (bits) Max.Sample Rate (samples/sec) # of Input Channels Input Type Interface Input Voltage Range (V) Max. Supply Current (A) MCP3001 10 200 1 Single-ended SPI 2.7 to 5.5 500 1 LSB -40 to +85 PDIP-8, SOIC-8, MSOP-8, TSSOP-8 - MCP3002 10 200 2 Single-ended SPI 2.7 to 5.5 650 1 LSB -40 to +85 PDIP-8, SOIC-8, MSOP-8, TSSOP-8 - MCP3004 10 200 4 Single-ended SPI 2.7 to 5.5 550 1 LSB -40 to +85 PDIP-14, SOIC-14, TSSOP-14 - MCP3008 10 200 8 Single-ended SPI 2.7 to 5.5 550 1 LSB -40 to +85 PDIP-16, SOIC-16 - MCP3021 10 22 1 Single-ended I2CTM 2.7 to 5.5 250 1 LSB -40 to +125 SOT-23A-5 MCP3221DM-PCTL, MXSIGDM MCP3221 12 22 1 Single-ended I2CTM 2.7 to 5.5 250 2 LSB -40 to +125 SOT-23A-5 MCP3221DM-PCTL, MXSIGDM MCP3201 12 100 1 Single-ended SPI 2.7 to 5.5 400 1 LSB -40 to +85 PDIP-8, SOIC-8, MSOP-8, TSSOP-8 DV3201A, DVMCPA, MXSIGDM MCP3202 12 100 2 Single-ended SPI 2.7 to 5.5 550 1 LSB -40 to +85 PDIP-8, SOIC-8, MSOP-8, TSSOP-8 DV3201A, DVMCPA, MXSIGDM MCP3204 12 100 4 Single-ended SPI 2.7 to 5.5 400 1 LSB -40 to +85 PDIP-14, SOIC-14, TSSOP-14 DV3204A, DVMCPA, MXSIGDM MCP3208 12 100 8 Single-ended SPI 2.7 to 5.5 400 1 LSB -40 to +85 PDIP-16, SOIC-16 DV3204A, DVMCPA, MXSIGDM MCP3301 13 100 1 Differential SPI 2.7 to 5.5 450 1 LSB -40 to +85 PDIP-8, SOIC-8, MSOP-8, TSSOP-8 DV3201A, DVMCPA, MXSIGDM MCP3302 13 100 2 Differential SPI 2.7 to 5.5 450 1 LSB -40 to +85 PDIP-14, SOIC-14, TSSOP-14 DV3204A, DVMCPA, MXSIGDM MCP3304 13 100 4 Differential SPI 2.7 to 5.5 450 1 LSB -40 to +85 PDIP-16, SOIC-16 DV3204A, DVMCPA, MXSIGDM Part # Temperature Range (C) Max. INL Packages Featured Demo Board MIXED SIGNAL - D/A Converters Resolution (Bits) DACs per Package Interface VREF Output Settling Time (s) DNL (LSB) Typical Standby Current (A) Typical Operating Current (A) Temperature Range (C) MCP4725 12 1 I2CTM VDD 6 0.75 1 210 -40 to +125 MCP4728 12 4 I2CTM Int/ VDD 6 0.75 0.04 800 MCP4821 12 1 SPI Y 4.5 1 0.3 330 MCP4822 12 2 SPI Y 4.5 1 0.3 415 MCP4921 12 1 SPI Ext 4.5 0.75 1 MCP4922 12 2 SPI Ext 4.5 0.75 TC1320 8 1 SMbus/ I2CTM Ext 10 0.8 TC1321 10 1 SMbus/ I2CTM Ext 10 2 0.1 Part # Packages Featured Demo Board SOT-23-6 MCP4725DM-PTPLS, MCP4725EV -40 to +125 MSOP-10 MCP4728EV -40 to +125 PDIP-8, SOIC-8, MSOP-8 - -40 to +125 PDIP-8, SOIC-8, MSOP-8 - 175 -40 to +125 PDIP-8, SOIC-8, MSOP-8 - 1 350 -40 to +125 PDIP-14, SOIC-14, TSSOP-14 - 0.1 350 -40 to +85 SOIC-8, MSOP-8 - 350 -40 to +85 SOIC-8, MSOP-8 - Signal Chain Design Guide 25 MIXED SIGNAL - Digital Potentiometers Device # of Taps # per Package Interface VDD Operating Range(1) Volatile/ Non-Volatile Resistance (ohms) INL (Max.) DNL (Max.) Temperature Range (C) Packages Featured Demo Board MCP4011 64 1 U/D 1.8V to 5.5V Volatile 2.1K, 5K, 10K, 50K 0.5 LSb 0.5 LSb -40 to +125 SOIC-8 MCP402XEV, MCP4XXXDM-DB MCP4012 64 1 U/D 1.8V to 5.5V Volatile 2.1K, 5K, 10K, 50K 0.5 LSb 0.5 LSb -40 to +125 SOT-23-6 MCP402XEV, SC70EV MCP4013 64 1 U/D 1.8V to 5.5V Volatile 2.1K, 5K, 10K, 50K 0.5 LSb 0.5 LSb -40 to +125 SOT-23-6 MCP402XEV, SC70EV MCP4014 64 1 U/D 1.8V to 5.5V Volatile 2.1K, 5K, 10K, 50K 0.5 LSb 0.5 LSb -40 to +125 SOT-23-5 MCP402XEV, SC70EV MCP4017 128 1 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 SC-70-6 SC70EV MCP4018 128 1 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 SC-70-6 SC70EV MCP4019 128 1 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 SC-70-5 SC70EV MCP40D17 128 1 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 SC-70-6 SC70EV SC70EV 2 MCP40D18 128 1 I CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 SC-70-6 MCP40D19 128 1 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 SC-70-5 SC70EV MCP4021 64 1 U/D 2.7V to 5.5V Non-Volatile 2.1K, 5K, 10K, 50K 0.5 LSb 0.5 LSb -40 to +125 SOIC-8 MCP402XEV, MCP4XXXDM-DB MCP4022 64 1 U/D 2.7V to 5.5V Non-Volatile 2.1K, 5K, 10K, 50K 0.5 LSb 0.5 LSb -40 to +125 SOT-23-6 MCP402XEV, SC70EV MCP4023 64 1 U/D 2.7V to 5.5V Non-Volatile 2.1K, 5K, 10K, 50K 0.5 LSb 0.5 LSb -40 to +125 SOT-23-6 MCP402XEV, SC70EV MCP4024 64 1 U/D 2.7V to 5.5V Non-Volatile 2.1K, 5K, 10K, 50K 0.5 LSb 0.5 LSb -40 to +125 SOT-23-5 MCP402XEV, SC70EV MCP41010 256 1 SPI 2.7V to 5.5V Volatile 10K 1 LSb 1 LSb -40 to +85 PDIP-8, SOIC-8 MCP4XXXDM-DB MCP41050 256 1 SPI 2.7V to 5.5V Volatile 50K 1 LSb 1 LSb -40 to +85 PDIP-8, SOIC-8 MCP4XXXDM-DB MCP41100 256 1 SPI 2.7V to 5.5V Volatile 100K 1 LSb 1 LSb -40 to +85 PDIP-8, SOIC-8 MCP4XXXDM-DB MCP42010 256 2 SPI 2.7V to 5.5V Volatile 10K 1 LSb 1 LSb -40 to +85 PDIP-14, SOIC-14, TSSOP-14 MCP4XXXDM-DB MCP42050 256 2 SPI 2.7V to 5.5V Volatile 50K 1 LSb 1 LSb -40 to +85 PDIP-14, SOIC-14, TSSOP-14 MCP4XXXDM-DB MCP42100 256 2 SPI 2.7V to 5.5V Volatile 100K 1 LSb 1 LSb -40 to +85 PDIP-14, SOIC-14, TSSOP-14 MCP4XXXDM-DB MCP4131 129 1 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 PDIP-8, SOIC-8, MSOP-8, DFN-8 MCP42XXDM-PTPLS MCP4132 129 1 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 PDIP-8, SOIC-8, MSOP-8, DFN-8 MCP42XXDM-PTPLS MCP4141 129 1 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 PDIP-8, SOIC-8, MSOP-8, DFN-8 MCP42XXDM-PTPLS MCP4142 129 1 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 PDIP-8, SOIC-8, MSOP-8, DFN-8 MCP42XXDM-PTPLS MCP42XXDM-PTPLS MCP4151 257 1 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 PDIP-8, SOIC-8, MSOP-8, DFN-8 MCP4152 257 1 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 PDIP-8, SOIC-8, MSOP-8, DFN-8 MCP42XXDM-PTPLS MCP42XXDM-PTPLS MCP4161 257 1 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 PDIP-8, SOIC-8, MSOP-8, DFN-8 MCP4162 257 1 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 PDIP-8, SOIC-8, MSOP-8, DFN-8 MCP42XXDM-PTPLS MCP4231 129 2 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 PDIP-14, SOIC-14, TSSOP-14, QFN-16 MCP4XXXDM-DB, MCP42XXDM-PTPLS MCP4232 129 2 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 MSOP-10, DFN-10 MCP42XXDM-PTPLS MCP4241 129 2 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 PDIP-14, SOIC-14, TSSOP-14, QFN-16 MCP4XXXDM-DB, MCP42XXDM-PTPLS MCP4242 129 2 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 MSOP-10, DFN-10 MCP42XXDM-PTPLS MCP4251 257 2 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 PDIP-14, SOIC-14, TSSOP-14, QFN-16 MCP4XXXDM-DB, MCP42XXDM-PTPLS MCP4252 257 2 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 MSOP-10, DFN-10 MCP42XXDM-PTPLS MCP4261 257 2 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 PDIP-14, SOIC-14, TSSOP-14, QFN-16 MCP4XXXDM-DB, MCP42XXDM-PTPLS MCP4262 257 2 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 MSOP-10, DFN-10 MCP42XXDM-PTPLS MCP4351 257 4 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1.0 LSb 0.5 LSb -40 to +125 TSSOP-20, QFN-20 TSSOP20EV MCP4352 257 4 SPI 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1.0 LSb 0.5 LSb -40 to +125 TSSOP-14 TSSOP20EV Note 1: Analog characteristics may be tested at different voltage ranges. Signal Chain Design Guide 26 MIXED SIGNAL - Digital Potentiometers (Continued) Device # of Taps # per Package Interface VDD Operating Range(1) Volatile/ Non-Volatile Resistance (ohms) INL (Max.) DNL (Max.) Temperature Range (C) MCP4361 257 4 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1.0 LSb 0.5 LSb -40 to +125 TSSOP-20, QFN-20 TSSOP20EV MCP4362 257 4 SPI 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1.0 LSb 0.5 LSb -40 to +125 TSSOP-14 TSSOP20EV MCP46XXDM-PTPLS Packages Featured Demo Board MCP4531 129 1 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 MSOP-8, DFN-8 MCP4532 129 1 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 MSOP-8, DFN-8 MCP46XXDM-PTPLS MCP4541 129 1 I2CTM 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 MSOP-8, DFN-8 MCP46XXDM-PTPLS MCP4542 29 1 I2CTM 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 MSOP-8, DFN-8 MCP46XXDM-PTPLS MCP4551 257 1 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 MSOP-8, DFN-8 MCP46XXDM-PTPLS 2 MCP4552 257 1 I CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 MSOP-8, DFN-8 MCP46XXDM-PTPLS MCP4561 257 1 I2CTM 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 MSOP-8, DFN-8 MCP46XXDM-PTPLS MCP4562 257 1 I2CTM 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 MSOP-8, DFN-8 MCP46XXDM-PTPLS MCP4631 129 2 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 TSSOP-14, QFN-16 MCP4XXXDM-DB, MCP46XXDM-PTPLS MCP4632 129 2 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 MSOP-10, DFN-10 MCP46XXDM-PTPLS MCP4641 129 2 I2CTM 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 TSSOP-14, QFN-16 MCP4XXXDM-DB, MCP46XXDM-PTPLS MCP4642 129 2 I2CTM 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 0.5 LSb 0.25 LSb -40 to +125 MSOP-10, DFN-10 MCP46XXDM-PTPLS MCP4651 257 2 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 TSSOP-14, QFN-16 MCP4XXXDM-DB, MCP46XXDM-PTPLS MCP4652 257 2 I2CTM 1.8V to 5.5V Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 MSOP-10, DFN-10 MCP46XXDM-PTPLS MCP4661 257 2 I2CTM 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 TSSOP-14, QFN-16 MCP4XXXDM-DB, MCP46XXDM-PTPLS MCP4662 257 2 I2CTM 2.7V to 5.5V Non-Volatile 5K, 10K, 50K, 100K 1 LSb 0.5 LSb -40 to +125 MSOP-10, DFN-10 MCP46XXDM-PTPLS Note 1: Analog characteristics may be tested at different voltage ranges. THERMAL MANAGEMENT THERMAL MANAGEMENT PRODUCTS - Temperature Sensors Part # Typical Accuracy (C) Maximum Accuracy @ 25C (C) Maximum Temperature Range (C) Vcc Range (V) Maximum Supply Current (A) Resolution (bits) Packages Featured Demo Board Serial Output Temperature Sensors MCP9800 0.5 1 -55 to +125 +2.7 to +5.5 400 9-12 SOT-23-5 MCP9800DM-TS1 MCP9801 0.5 1 -55 to +125 +2.7 to +5.5 400 9-12 SOIC-8 150 mil, MSOP-8 MCP9800DM-TS1 MCP9802 0.5 1 -55 to +125 +2.7 to +5.5 400 9-12 SOT-23-5 MCP9800DM-TS1 MCP9803 0.5 1 -55 to +125 +2.7 to +5.5 400 9-12 SOIC-8 150 mil, MSOP-8 MCP9800DM-TS1 MCP9804 0.25 1 -40 to +125 +2.7 to +5.5 400 12-bits MSOP-8, DFN-8 TMPSNSRD-RTD2, TMPSNSRD-TCPL1 MCP9805 2 3 -40 to +125 3.0 to 3.6 500 10 TSSOP-8, DFN-8 - MCP98242 2 3 -40 to +125 3.0 to 3.6 500 10 TSSOP-8, DFN-8, TDFN-8, UDFN-8 - MCP98243 0.5 3 -40 to +125 3.0 to 3.6 500 11 TSSOP-8, DFN-8, TDFN-8, UDFN-8 - TC72 0.5 2 -55 to +125 +2.7 to +5.5 400 10 MSOP-8, DFN-8 TC72DM-PICTL TC74 0.5 2 -40 to +125 +2.7 to +5.5 350 8 SOT-23-5, TO-220-5 TC74DEMO TC77 0.5 1 -55 to +125 +2.7 to +5.5 400 12 SOIC-8 150 mil, SOT-23-5 TC77DM-PICTL TCN75 0.5 3 -55 to +125 +2.7 to +5.5 1000 9 SOIC-8 150 mil, MSOP-8 - TCN75A 0.5 3 -40 to +125 +2.7 to +5.5 400 9-12 SOIC-8 150 mil, MSOP-8 - Signal Chain Design Guide 27 THERMAL MANAGEMENT PRODUCTS - Temperature Sensors Part # Typical Accuracy (C) Maximum Accuracy @ 25C (C) Maximum Temperature Range (C) Vcc Range (V) Maximum Supply Current (A) Resolution (bits) Packages Featured Demo Board Logic Output Temperature Sensors MCP9509 0.5 NA -40 to +125 2.7 to 5.5 50 - SOT-23-5 - MCP9510 0.5 NA -40 to +125 2.7 to 5.5 80 - SOT-23-6 - TC620 1 3 -55 to 125 4.5 to 18 400 - PDIP-8, SOIC-8 150 mil - TC621 1 3 -55 to 125 4.5 to 18 400 - PDIP-8, SOIC-8 150 mil - TC622 1 5 -40 to +125 4.5 to 18 600 - PDIP-8, SOIC-8 150 mil, TO-220-5 - TC623 1 3 -40 to +125 2.7 to 4.5 250 - PDIP-8, SOIC-8 150 mil - TC624 1 5 -40 to +125 2.7 to 4.5 300 - PDIP-8, SOIC-8 150 mil - TC6501 0.5 4 -55 to 135 2.7 to 5.5 40 - SOT-23-5 - TC6502 0.5 4 -55 to 135 2.7 to 5.5 40 - SOT-23-5 - TC6503 0.5 4 -55 to 135 2.7 to 5.5 40 - SOT-23-5 - TC6504 0.5 4 -55 to 135 2.7 to 5.5 40 - SOT-23-5 - Voltage Output Temperature Sensors MCP9700 1 4 -40 to +150 2.3 to 5.5 6 - SC-70-5, SOT-23-3, TO-92-3 MCP9700DM-PCTL MCP9700A 1 2 -40 to +150 2.3 to 5.5 6 - SC-70-5, SOT-23-3, TO-92-3 MCP9700DM-PCTL MCP9701 1 4 -40 to +125 +3.1 to +5.5 6 - SC-70-5, SOT-23-3, TO-92-3 MCP9700DM-PCTL MCP9701A 1 2 -40 to +125 +3.1 to +5.5 6 - SC-70-5, SOT-23-3, TO-92-3 MCP9700DM-PCTL TC1046 0.5 2 -40 to +125 2.7 to 4.4 60 - SOT-23-3 - TC1047 0.5 2 -40 to +125 2.7 to 4.4 60 - SOT-23-3 TC1047ADM-PICTL TC1047A 0.5 2 -40 to +125 +2.5 to +5.5 60 - SOT-23-3 TC1047ADM-PICTL TC1047A 0.5 2 -40 to +125 +2.5 to +5.5 60 - SOT-23B-3 - POWER MANAGEMENT POWER MANAGEMENT - Voltage References Part # Vcc Range (V) Output Voltage (V) Max. Load Current (mA) Initial Accuracy (max.%) Temperature Coefficient (ppm/C) Maximum Supply Current (A @ 25C) Packages MCP1525 2.7 to 5.5 2.5 2 1 50 100 SOT-23B-3, TO-92-3 MCP1541 4.3 to 5.5 4.096 2 1 50 100 SOT-23B-3, TO-92-3 Signal Chain Design Guide 28 Stand-Alone Analog and Interface Portfolio Thermal Management Power Management Linear Mixed-Signal Temperature Sensors LDO & Switching Regulators Op Amps Fan Speed Controllers/ Fan Fault Detectors Charge Pump DC/DC Converters Programmable Gain Amplifiers Digital Potentiometers Power MOSFET Drivers Comparators D/A Converters PWM Controllers System Supervisors Voltage Detectors Voltage References Li-Ion/Li-Polymer Battery Chargers A/D Converter Families Safety & Security Photoelectric Smoke Detectors V/F and F/V Converters Energy Measurement ICs Interface CAN Peripherals Infrared Peripherals LIN Transceivers Serial Peripherals Ethernet Controllers USB Peripheral Ionization Smoke Detectors Ionization Smoke Detector Front Ends Piezoelectric Horn Drivers Analog and Interface Attributes Robustness MOSFET Drivers lead the industry in latch-up immunity/stability High performance LIN and CAN transceivers Low Power/Low Voltage Op Amp family with the lowest power for a given gain bandwidth 600 nA/1.4V/14 kHz bandwidth op amps 1.8V charge pumps and comparators 1.6 A LDOs Low power ADCs with one-shot conversion Integration One of the first to market with integrated LDO with Reset and Fan Controller with temperature sensor PGA integrates MUX, resistive ladder, gain switches, high-performance amplifier, SPI interface Industry's first 12-bit quad DAC with non-volatile EEPROM Delta-Sigma ADCs feature on-board PGA and voltage reference Highly integrated charging solutions for Li-ion and LiFePO4 batteries Space Savings Resets and LDOs in SC70 package, A/D and D/A converters in SOT-23 package CAN and IrDA(R) Standard protocol stack embedded in an 18-pin package Accuracy Low input offset voltages High gains Innovation Low pin-count embedded IrDA Standard stack, FanSenseTM technology Select ModeTM operation Industry's first op amp featuring on-demand calibration via mCal technology Digital potentiometers feature WiperLockTM technology to secure EEPROM For more information, visit the Microchip web site at: www.microchip.com Signal Chain Design Guide 29 Support Training Microchip is committed to supporting its customers in developing products faster and more efficiently. 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