Design & Integration Files
- Bill of Materials
- Gerber Files
- PADS Files
- Assembly Drawing
Part Numbers with "Z" indicate RoHS Compliance. Boards checked are needed to evaluate this circuit
- EVAL-CN0364-SDPZ ($110.00) PLC/DCS Quad Channel Voltage and Current Input with HART Compatibility
- EVAL-SDP-CB1Z ($99.00) Eval Control Board
Software such as C code and/or FPGA code, used to communicate with component's digital interface.
Features & Benefits
- Quad Channel Voltage and Current Inputs
- Fully Isolated
- HART Compatibility
Markets & Technology
- Instrumentation & Measurement
- Industrial Automation Technology (IAT)
- Aerospace and Defense
Circuit Function & Benefits
The analog input circuit is designed for group isolated industrial analog inputs and can support voltage and current input ranges including ±5 V, ±10 V, 0 V to +5 V, 0 V to +10 V, +4 mA to +20 mA, and 0 mA to +20 mA.
The circuit is powered from a standard 24 V bus supply and generates an isolated 5 V system supply voltage.
The AD5700-1 is the industry’s lowest power and smallest footprint HART-compliant modem and is used in conjunction with the current input channels to form a HART-compatible, 4 mA to 20 mA receiver solution. The AD5700-1 includes a precision internal oscillator that provides additional space savings, especially in isolated applications.
The ADG704 multiplexer provides HART connectivity to the multiple current input channels.
The ADuM5211 isolates two data channels (Tx, Rx) and also provides the 5 V power isolation via integrated isoPower® technology. The ADuM3151 SPIsolator provides serial peripheral interface (SPI) isolation at clock rates of up to 17 MHz (B grade), as well as isolating three additional data channels.
The ADP2441 36 V, step-down, dc-to-dc regulator accepts an industrial standard 24 V supply, with wide tolerance on the input voltage. The ADP2441 steps the input voltage down to 5 V to power all controller side circuitry. The circuit also includes standard external protection on the 24 V supply terminals.
Figure 1. PLC/DCS Quad Channel Voltage and Current Input Front End (Simplified Schematic: All Connections and Decoupling Not Shown)
Voltage Input Circuit
Figure 2 shows the voltage input network for Channel 1.
Figure 2. Voltage Input Equivalent Circuit (Simplified)
The R1, R2, R3, and R4 resistors form a differential resistor divider. The matching of these resistors is critical to the dc accuracy of the circuit. Single point calibration is recommended to remove the initial errors. Multipoint calibration can be used to cancel temperature drift effects. The board is populated by default with 0.1%, 25 ppm/°C resistors for R1, R2, R3, and R4.
The R5 and R6 resistors set the common-mode voltage for the ADC. The AD7173-8 has an allowable input voltage range of 0 V to 3.9 V. The bias voltage of +2.2 V, along with the input divider resistors, level shifts and attenuates the ±10 V input signal to ±1.1 V centered on a common-mode voltage of +2 V at the ADC input.
Input common-mode noise filtering is provided by R1||R3/C1 and R2||R4/C2, and is approximately 200 kHz. Differential noise filtering is provided by R1||R3, R2||R4, and C3, and is approximately 20 kHz.
Table 1 summarizes the parameters of the four voltage input channels.
Table 1. Voltage Input Circuit Parameters (Maximum Values Based on Worst-Case Calculations)
|kΩ||Resistor divider of 402 kΩ and 49.9 kΩ|
|Initial Error from Resistors||0.18||%FSR max||25°C, uncalibrated; assumed 0.1% resistors|
|Error from Input Leakage||±0.01||%FSR||±10 V range; AD7173-8,±2 nA typical leakage|
|Error from Resistor Drift||18
|Assumed 10 ppm/°C resistors
Assumed 5 ppm/°C resistors
|Error from Reference Drift||10||ppm/°C max||Internal reference|
|1 input enabled (14.7 bit noise-free code resolution for ±10 V)
4 channels, each fully settled, sinc5+1 filter (14.7 bit noise-free code resolution for ±10 V)
4 channels, each fully settled, 50 HZ/60 Hz reject (18.8 bit noise-free code resolution for ±10 V)
Figure 3 shows the current input network for Channel 1.
Figure 3. Current Input Equivalent Circuit (Simplified)
The circuit has four current input channels, supporting a maximum input range of 0 mA to 24 mA. The input impedance of the circuit is 250 Ω, and the input is referenced to ground. A precision 100 Ω current sense resistor is used so that a 24 mA input produces 2.4 V, which is within the 2.5 V full-scale range of the AD7173-8 (using the internal 2.5 V voltage reference). The board is populated by default with a 0.1%, 10 ppm/°C RSENSE resistor.
There are two input paths to separate ADC inputs. The fast input path is for channels not using HART, and the slow input path is for channels using HART.
The fast input path allows signals up to the full input bandwidth of the Σ-Δ ADC. It is also possible to use the internal sinc filters to reject the 1.2 kHz and 2.2 kHz HART frequencies. However, using the sinc filters requires running the relevant channel at the 400 SPS data rate (sinc3 filter), which increases the time required to convert all four channels.
The slow input contains a 16 Hz double-pole filter, which filters out the 1.2 kHz and 2.2 kHz HART digital signaling frequencies. Using this input, the Σ-Δ ADC can still run at its fast data rate and also reject the HART digital signaling frequencies. The time required to convert all four channels is not reduced. Operating the ADC at its fast data rate is especially useful if not all channels have HART enabled.
Table 2 summarizes the current input circuit parameters.
Table 2. Current Input Circuit Parameters (Maximum Values Based on Worst-Case Calculations)
|Error from Resistor||N/A1||%FSR max||Per RSENSE resistor specifications|
|Error from Resistor Drift||N/A1||ppm/°C max||Per RSENSE resistor specifications|
|Error from Reference Drift||10||ppm/°C max||Internal reference|
|1 input enabled (14.8 bit noise-free code resolution for 0 mA to 20 mA)
4 channels, each fully settled, sinc5+1 filter (14.8 bit p-p resolution for 0 mA to 20 mA)
4 channels, each fully settled, 50 Hz/60 Hz reject (18.1 bit p-p resolution for 0 mA to 20 mA)
Slow input providing HART filtering
1 N/A = not applicable.
HART Input and Output Circuit
Figure 4 shows the HART input and output circuit.
Figure 4. HART Input and Output Circuits (Simplified)
The HART functionality is multiplexed between the four current input channels. The HART input and output networks are shared between the four channels using the two ADG704 multiplexers (SW1 and SW2 in Figure 4).
The HART input circuitry consists of a HART band-pass filter formed by R3, C1, C2, R4, and R5. This filter is described in the AD5700-1 data sheet. A switch (SW1) is used in each channel to switch the HART input circuitry to the active HART channel. The 150 kΩ resistor (R3) is present on each channel and is part of the HART band-pass filter, but also provides additional protection for the switch (SW1). The HART input connects directly to the current input terminal to ensure that the correct voltage levels are received at the ADC_IP pin of the AD5700-1.
A switch (SW2) is used in each channel to switch the HART output circuitry to the active HART channel. Capacitor C3 couples the HART signal. The combination of R1, C3, R6, and R7 was carefully chosen to ensure that the voltage of the HART_OUT pin of the AD5700-1 does not fall below GND during a 25 Hz, 4 mA to 20mA input signal (representing the fastest allowable slew rate for a HART-enabled device).
Figure 5. Power Supply Circuit (Simplified Schematic: All Connections Not Shown)
Power Supply Circuit
The evaluation board is powered by a 5.5 V to 36 V dc power supply and uses an on-board switching regulator to provide the 5 V supply to the system, as shown in Figure 5. In the test setup, the 5 V also powers the EVAL-SDP-CB1Z system demonstration platform (SDP) board. The EVAL-SDP-CB1Z SDP board provides a regulated 3.3 V for the VIO voltage.
The high switching frequency of the ADP2441 allows minimal output voltage ripple even when small inductors are used. Selecting the size of the inductor involves considering the trade-off between efficiency and transient response. A smaller inductor results in larger inductor current ripple, which provides excellent transient response but degrades efficiency. Due to the high switching frequency of the ADP2441, using shielded ferrite core inductors is recommended because of their low core losses and low electromagnetic interference (EMI).
In the Figure 5 circuit, the switching frequency is approximately 1 MHz with the 88.7 kΩ external resistor. The inductor value of 12 μH (Coilcraft LPS6235-123MLC) is chosen from Table 8 of the ADP2441 data sheet.
The circuit is connected to the field supply of 5.5 V to 36 V using screw terminals. The EARTH terminal can be connected to an external earth connection or to the GND terminal if an external earth connection is not used.
Power inductors (DR73-102-R), varistors (V56ZA3P, 56 V), power diode (S2A-TP, 50 V), and a 1.1 A fuse provide additional input protection against high voltage transient events.
Evaluate the system noise by shorting the input terminals for each channel, which results in a zero differential voltage for the voltage input channels and grounded input for the current input channels. Gather the data with the inputs shorted, and compute the code spread and noise-free code resolution from the set number of samples.
This noise test can be done using the CN-0364 Evaluation Software. The code spread and noise-free code resolution of each channel can be obtained and the data displayed in a histogram. Figure 6 shows a histogram from sample data gathered from the voltage input of Channel 1.
Figure 6. Channel 1 Voltage Input, Inputs Shorted and Biased to Reference Voltage, 31.25 kSPS, Sinc5+1 Filter, 2000 Samples (15.8 Bit Noise-Free Code Resolution)
The HART functionality was tested according to the HART physical layer test specification (HCF-TEST-2). The circuit met the requirements for the HART physical layer. More details on the HART specifications can be obtained directly from the HART Communication Foundation.
The rejection of the ADC input to the HART 1.2 kHz and 2.2 kHz signals was also measured. Table 3 shows the results.
Table 3. Rejection of 1.2 kHz and 2.2 kHz HART Frequencies
|Operating Mode||Frequency (kHz)||Rejection(dB)|
|Slow Input Path, 31 kSPS Sinc5+1 Filter||1.2
|Fast Input Path, 400 SPS Sinc3 Filter||1.2
For applications that require more than 150 mW of isolated power, the ADuM540x or ADuM347x can be used. The ADuM540x use isoPower technology to supply up to 500 mW of isolated power. The ADuM347x drive an external, discreet transformer to supply up to 2 W at up to 70% efficiency.
Circuit Evaluation & Test
The EVAL-CN0364-SDPZ evaluation board features PMOD compatible headers for integration with external controller boards.
The CN-0364 Evaluation Software communicates with the SDP board to configure and capture data from the EVAL-CN0364-SDPZ evaluation board.
The following equipment is needed:
- A PC with a USB port and Windows® Vista (32-bit) or Windows 7 (32-bit)
- The EVAL-CN0364-SDPZ circuit evaluation board
- The EVAL-SDP-CB1Z SDP controller board
- The CN-0364 Evaluation Software
- A precision voltage and current source
- A power supply: 5.5 V to 36 V dc at 500 mA
Install the CN-0364 Evaluation Software, which is available for download. Follow the on-screen prompts to install and use the software. More information is available in the CN-0364 Software User Guide.
Functional Block Diagram
Figure 7 shows a function block diagram of the test setup.
Figure 7. Test Setup Functional Block Diagram
The EVAL-CN0364-SDPZ evaluation board connects to the EVAL-SDP-CB1Z SDP board through a 120-pin mating connector found on both boards. The CN-0364 Evaluation Software and the SDP board allow the data to be analyzed using a PC.
The CN-0267 circuit (a complete 4 mA to 20 mA loop powered field instrument with HART interface) can be connected to easily test the HART physical layer functionality. The CN-0267 hardware responds to the HART commands available in the CN-0364 Evaluation Software.
External controllers can also be used to communicate with and power the evaluation board using the PMOD headers for SPI and UART communication.
Precision voltage and current sources can be used as input to the analog front end to evaluate system performance.
Figure 8 shows a photo of the EVAL-CN0364-SDPZ evaluation board.
Figure 8. Photo of EVAL-CN0364-SDPZ Evaluation Board
|AD5700-1||Low Power HART Modem with Precision Internal Oscillator||
Low Power, 8-/16-Channel, 31.25 kSPS, 24-Bit, Highly Integrated Sigma-Delta ADC
|ADG704||CMOS, Low Voltage 2.5 Ω 4-Channel Multiplexer||
|ADP2441||36 V,1 A, Synchronous, Step-Down DC-DC Regulator||
|ADUM3151||3.75 kV, 7-Channel, SPIsolator Digital Isolators for SPI (with 2/1 Aux channel directionality)||
Dual-Channel Isolators with Integrated DC-to-DC Converter (1/1 Channel Directionality)
|AD7176-2||24-Bit, 250 kSPS Sigma Delta ADC with 20 µs Settling||
|AD7175-2||24-Bit, 250 kSPS, Sigma-Delta ADC with 20 µs Settling and True Rail-to-Rail Buffers||
|AD7172-2||Low Power, 24-Bit, 31.25 kSPS, Sigma-Delta ADC with True Rail-to-Rail Buffers||
|AD7177-2||32-Bit, 10 kSPS, Sigma-Delta ADC with 100 µs Settling and True Rail-to-Rail Buffers||
|AD7172-4||Low Power, with 4- or 8-channel, 24-bit, 31.25 kSPS, Sigma-Delta ADC with True Rail-to-Rail Buffers||