Bipolar power supply and isolated signal transmission with MagI³C-FIMM

ANS019 by Timur Uludag

01. INTRODUCTION

Industrial plants, such as warehouse logistics, filling plants, rolling mills, conveyor belts and printing presses, generally require the use of a selection of the following elements for safe operation:

• Isolation amplifiers, analog-to-digital converters
• Isolation of digital circuits
• Interfaces/bus isolation - RS232, RS485, CAN, Interbus, Profibus
• Measurement and data acquisition

Figure 1: Typical industrial application: warehouse logistics system.

All these applications have one thing in common: the isolation of their supply voltage from the bus voltage. Why should you galvanically isolate a supply from a bus or from switching components? Galvanic isolation prevents transient interference from the supply voltage from propagating into the bus and disrupting its operation.

02. DC/DC POWER MODULE – WPME-FIMM

As an isolated DC/DC converter, a power module with galvanic isolation provides a reliable supply for an analog-to-digital converter (ADC) in the warehouse logistics example. More precisely, it is the isolated MicroModule 1769205132 of the FIMM series (Fixed Isolated MicroModule), which combines the properties of an isolated power module with those of our classic MicroModules. By using chiplet SIP technology, it was possible to reduce the dimensions by 80%, resulting in a module with the dimensions 9 x 7 x 3.1 mm³. The board space requirements are reduced by more than 50% compared to a standard SMT-8 power module (9 x 7 mm² versus 13.2 x 12.2 mm²).

The MagI³C power module 1769205132 is based on a full bridge topology. The module integrates a switching power stage, control circuitry, rectifier diodes, input and output capacitors and a transformer. Since there is no feedback path from the output to the input, the duty cycle is fixed at 50 % and is independent of the load. The output voltage is unregulated and is determined by the transformer turns ratio. The output power of 1 W can be provided up to an ambient temperature of T_A = 100°C without any output current derating. The parasitic coupling capacitance between the primary and secondary side has a typical value of 8 pF due to the design. With an efficiency of 91 % it is the “best-in-class” in the complete isolated power module portfolio of Würth Elektronik.

Figure 2: Structure of the isolated MicroModule 1769205132 of the FIMM series.

Galvanically isolated DC/DC converters are specifically designed to implement voltage isolation within distributed power supply systems. The FIMM module is particularly suitable for applications sensitive to supply interference, such as analog low-frequency circuits and relay-controlled circuits. The low parasitic capacitance between the primary and secondary sides ensures a high degree of decoupling from high-frequency interference. Furthermore, this low parasitic capacitance mitigates common-mode interference propagation from the primary switching side to the secondary side of the converter.

03. DECOUPLED DUAL VOLTAGE SUPPLY FOR SENSITIVE SENSORS

Figure 3: Example of a sensor application using a decoupled dual voltage supply (red board).

Applications such as measurement and data acquisition are often built with ADCs, which convert the analog measured values, such as a temperature value or a current, into a digital quantity. For the acquisition of positive and negative measurement signals, a dual voltage supply is required. Usually a supply of ±5 V is used in such an application. The resolution an ADC can provide, i.e. how many bits it effectively makes available, depends, among other things, on the noise component of the supply voltage. The red circuit board in the application above generates a galvanically isolated dual voltage of ± 5 V from an input voltage of 5 V.

Special features of the circuit are:

• Very low residual ripple at the output
• Broadband decoupling between input and output

The dual voltage supply consists broadly of four different function blocks (see figure 4):

Input protection circuit. The protection circuit integrates reverse polarity protection and voltage transient protection.

Input filter. The first filter stage serves to attenuate conducted interference levels. Harmonics generated by the switching operations of the DC/DC converter in the direction of the supplying source are reduced in their amplitude. On the other hand, interference can reach the power module via the power supply and is attenuated by the filter.

The power module itself. The power module converts the voltage and provides galvanic isolation between input and output.

Output filter. The current supplied by the power module is a superposition of a DC current with an AC component. The AC component is the part that is reduced in amplitude by the filter in order to provide a “clean” DC voltage for the application to be supplied, such as an ADC.

Figure 4: Schematic for dual isolated voltages.

3.1 Input protection circuit

In the following sections, the circuit is explained block by block with regard to its function. Voltage protection on the input-side:

Figure 5: Over voltage protection at the input-side.

The protective circuit on the input side features a two-stage design (figure 5). The diode D1 fulfills two tasks: it protects the input from negative transient interference and prevents damage to the input of the power module in case of reverse supply polarity. With a forward voltage of 0.3 V @ 0.3 A, it clamps the voltage to a value below the maximum operating value specified for the power module. Diode D2 protects the circuit from positive voltage transients. At a positive voltage transient between 6 to 9V from the cathode to the anode, diode D2 conducts. The effective clamping voltage is then typically 5.7 V and thus in the range of the absolute maximum rating of the power module.

3.2 Input filter

Figure 6: Input filter – π-configuration.

The power module operates with a typical internal switching frequency of 300 kHz. The upstream power supplies typically have a switching frequency of 50 to 500 kHz. This results in a filter combination that already has an attenuation of 50 to 75 dB at approximately 100 kHz in order to filter any transient interferences. The combination of C1, L1 and C2 forms a π-filter structure. The values of the individual filter components were chosen with the aim of providing an insertion loss of approximately 50 dB starting at 100 kHz.

The curve in figure 7 of the insertion loss of the first filter stage shows that an attenuation of approx. 80 dB is already achieved from 50 kHz. The calculation/simulation can be carried out with the filter designer in REDEXPERT. The tool uses the real properties of the components based on measurements for the calculation. This way, the simulated results correspond better with the real components. The calculation of the insertion loss was carried out with a source and load impedance of 50 Ω. Essential for a high insertion loss in practice is an RF-compatible design that avoids coupling between the components.

Figure 7: Plot of the insertion loss of the first filter stage as a simulation in REDEXPERT

The diagrams in figure 8 and figure 9 show the real measured values for the ripple voltage at the filter input and output.

Figure 8: Ripple voltage at the input of the power module.

The ripple voltage was measured using a 10:1 probe with a bandwidth limitation set to 20 MHz. With only 10 mV_PP, the AC components of the power module output are already very low. In comparison, the AC component introduced by the upstream power supply unit is many times higher with a typical value of 50 to 150 mV_PP. The portion that the power module “feeds” into the DC bus is thus negligible. The measurement result in figure 9 shows the effect of the π-filter very clearly. The AC component was attenuated to a value of less than 5 mV_PP. If we now look at the filter from the point of view of the bus voltage, i.e. from the upstream power supply unit as the source into the power module, we can expect the same effect on the AC component since the π-filter is constructed symmetrically.

Figure 9: Ripple voltage after the π-filter.

3.3 Output filter

Figure 10: Output filter - coupled inductor configuration - example +5V output.

Due to its principle of operation, the output voltage of a DC/DC converter does not provide a pure DC voltage such as that provided by a linear regulator. It is rather a combination of a DC voltage with a superimposed AC component. The AC component is specified in the data sheet as “output voltage ripple & noise” value in mVPP indicating the peak to peak amplitude of the output voltage. ADC circuits are sensitive to such values, as they can only work optimally with a small interference signal from their supply, which must be lower than the resolution of the ADC. The circuit shown in figure 10 is a filter that reduces the interference voltage of the FIMM on the output side. The linear two-port filter is constructed from a coupled inductance, with windings L2a/L2b and capacitors C3 and C4.

Winding L2a conducts the DC component to the load (like a “smoothing choke”), while the AC component flows to ground via winding L2b and capacitor C4. The impedance behavior of capacitor C4 causes it to discharge the high-frequency component to ground.

The magnetic coupling between the two windings, i.e. the negative feedback inductance, which is described by the coupling factor k, is essential for the filter function.

Due to the winding orientation of the two windings of the coupled inductance, the AC portion of the current flowing through winding L2b is transferred to winding L2a. The AC portion of the current is then superimposed on the DC/AC current, whereby the AC portion is cancelled out in the load current as well as compensated via the magnetic coupling and thus reduced.

The factor k is used to indicate the coupling between two coil windings, with a value of 1 indicating 100% coupling between the two windings. Due to the circuit design, which is similar to a second-order filter, coupled inductors should be used whose k value is < 0.99, otherwise the circuit will easily get into a series resonance (notch filter) and will show a lower filter effect in the frequency range above the resonant frequency. Ideally a k of less than 0.98 should be used. The coupled inductor WE-DD 744877220 used here has a coupling factor of approximately 0.98. The capacitors used must have the lowest possible ESR value in order to achieve the desired filter effect. For example, the aluminum polymer capacitor WCAP-PTHR 870055673002, which has an ESR value of less than 100 mΩ in the frequency range from 1 kHz to 50 MHz, can be used as a 22 μF capacitor.

The measurement plots in figures 11 and 12 show, that - for the ripple voltage of the +5 V branch a reduction of up to 50% of the AC component - compared to the unfiltered value - could be achieved.

Figure 11: Ripple voltage output power module - example +5V output (ca. 10 mVpp without spikes).

Figure 12: Ripple voltage output coupled inductor - example +5V output (ca. 5 mVpp without spikes).

04. GALVANICALLY ISOLATED MEASUREMENT SIGNAL TRANSMISSION

If electrical signals such as measured values have to be transmitted over a long distance, interference caused by couplings through parallel cables can distort the measured values.

Figure 13: Reference design for isolated data transmission based on the FIMM 1769205132

A remedy for this is to transmit the signals as well as the supply in a galvanically isolated manner, as this ensures decoupling through galvanic isolation and balancing which reduces common mode interference (CM). The circuit above makes it possible to transmit DC voltage in the range from 0 to +4 VDC and a pulsed DC voltage (AC voltage with offset) up to a frequency of 5 kHz, limited to 10 kHz, in a galvanically isolated manner.

4.1 Principle description of the mode of operation

1. Signal transmission

Figure 14: Principle function of signal transmission, galvanically isolated.

The LED of an optocoupler is controlled by the signal to be transmitted via an operational amplifier.

Figure 15: CTR curve of the optocoupler WL-OCPT 140816140410, V_CE = 5 V.

The linear relationship between the input voltage and the LED luminous intensity is essential for a signal-true transmission. The LED must therefore be operated in the “linear” range of its characteristic curve (see figure 15). Outside the linear range, signal-true transmission can no longer be guaranteed. The phototransistor of the optocoupler receives the light emitted by the LED and controls another operational amplifier according to the luminous intensity.

Figure 17: Isolated signal transmission – for the detailed schematics see Appendix.

2. Power supply

Figure 16: Galvanically isolated power supply.

The supply voltage of the primary circuit is provided directly by a DC/DC converter from an external voltage source (in this case a DC bus with 12 V). The supply of the secondary circuit is decoupled via a second DC/DC converter, the FIMM module U4. Since the supply voltage of the primary circuit is too high to be used directly as an input voltage for the FIMM module, the bus voltage is first reduced with a MicroModule U3 (171930601).

4.2 Signal transmission – primary side

The operational amplifier U1A is connected in a non-inverting configuration and two negative feedbacks have been realized:

1. C5 for negative feedback in the higher frequency range. This reduces overshoot and noise.
2. Optocoupler Q2 (WL-OPCT 140816140410) as current compensation to compensate for the non-linearity of optocoupler Q1 (identical with Q2). The LEDs of Q1 and Q2 are in series, where the phototransistor of Q1 controls the output circuit, and that of Q2 the current feedback from the primary circuit (U1A). As long as the diode current remains in the lower range of the characteristic curve, the non-linearity of the CTR is largely compensated for by the forward current IF of the two transmitting diodes. In the circuit, the diode current is limited by R6 (4.7 kΩ).

4.3 Signal transmission – secondary side

The current through the transistor of the optocoupler Q1 is dependent on the input voltage. Together with the resistor R3 (4.7 kΩ), the collector-emitter path forms a voltage divider that determines the current through the transistor in the conducting state and the DC offset at the non-inverting input of the operational amplifier U2A. At the output of the operational amplifier, with a negative feedback loop, the circuit is protected against transient voltages and short circuits by a pair of diodes (D2, D5) and a 220 Ω resistor (R2). The LED indicates the relative amplitude and frequency of the DC voltage and AC voltage signals at the input.

4.4 Power Supply On the secondary side, the operational amplifier U2A is supplied via the galvanically decoupled voltage of the FIMM module. The +12V bus voltage is reduced to 5 V via the MicroModule (U3) and galvanically isolated with the FIMM module (U4). The very small parasitic capacitance (typically 8 pF) of the FIMM module between input and output makes it possible to separate the secondary side of the circuit from the primary circuit. Thus, both common-mode interference of the circuit itself and of connected peripherals, such as sensors, are effectively suppressed or not generated at all.

Figure 18: Signal transmission at 900Hz.

The measurement plot above shows that the output signal (purple) has only a slight deviation from the original square wave signal shape (blue). As the frequency rises, the signal to be transmitted is “grounded”, i.e. the harmonics of the square-wave signal are missing and an approximation to a sinusoidal form can be recognized. The effects that come into play here are due to the limited transmission bandwidth of the optocoupler.

Figure 19: Signal transmission at 3000Hz.

The signal integrity here is largely dependent on the linearity of the optocoupler over the frequency.

4.5 Input Filter

The multi-stage input filter provides attenuation over a wide frequency range from conducted interference voltages, but also ensures that the output voltage is almost free of ripple. The filter is an extended form of the π-filter already discussed. 

FIMM layout recommendation:

Figure 20: The FIMM module provides two separate ground connections each for input and output voltages.

Care has to be taken that the FIMM module has two separate ground connections: pins 1 and 2 for the primary side and pins 3 and 4 for the secondary side. From a layout point of view it must be ensured that the primary and secondary sides are capacitively decoupled from each other. The input and output capacitors (C_IN and C_OUT) must be placed as close as possible to the input and output terminals of the module, respectively. This minimizes the current conduction loops, limiting the area of copper, which experience large changes in current during operation of the module. Inserting distance between the power module and the input filter reduces the effect of radiated coupling from the switching circuitry and the filter capacitor, CF, in the LC input filter. In practice, a distance of roughly 2.5 cm is sufficient. More detailed information on the layout can be found in the data sheet of the FIMM in the section “DESIGN EXAMPLE”. A layout recommendation for ALTIUM can be downloaded from the online catalogue in the “DESIGN EXAMPLE” section.

05. SUMMARY

Both applications require an isolated supply for their function. The galvanic isolation ensures high decoupling of RF interference and output voltage with very low ripple/residual noise. The schematic below shows another application of an isolated power module with a low coupling capacitance between primary and secondary side. Here, the voltage supply of the high and low side driver of a SiC / GaN FET half-bridge is galvanically decoupled. Modern SiC FETs are characterized by a high ΔV/Δt during switching. The higher this slope is, the more displacement current flows over this parasitic capacitance. A high dielectric displacement current permanently degrades the insulation barrier, interferes with the control signals and leads to common-mode currents, which are a typical cause of EMC problems.

Figure 21: FIMM as high and low side supply.

Insight into GaN/SiC control is offered by the Application Note ANP082 „Auxiliary supply requirements for SiC/GaN gate driver systems“.

A. Appendix

A.1 Schematic

Circuit diagram of the decoupled dual voltage supply for sensitive sensors from section 03.

Circuit diagram of the galvanically isolated measuring signal transmission from section 04.

IMPORTANT NOTICE

The Application Note is based on our knowledge and experience of typical requirements concerning these areas. It serves as general guidance and should not be construed as a commitment for the suitability for customer applications by Würth Elektronik eiSos GmbH & Co. KG. The information in the Application Note is subject to change without notice. This document and parts thereof must not be reproduced or copied without written permission, and contents thereof must not be imparted to a third party nor be used for any unauthorized purpose. Würth Elektronik eiSos GmbH & Co. KG and its subsidiaries and affiliates (WE) are not liable for application assistance of any kind. Customers may use WE’s assistance and product recommendations for their applications and design. The responsibility for the applicability and use of WE Products in a particular customer design is always solely within the authority of the customer. Due to this fact it is up to the customer to evaluate and investigate, where appropriate, and decide whether the device with the specific product characteristics described in the product specification is valid and suitable for the respective customer application or not. The technical specifications are stated in the current data sheet of the products. Therefore the customers shall use the data sheets and are cautioned to verify that data sheets are current. The current data sheets can be downloaded at www.we-online.com. Customers shall strictly observe any product-specific notes, cautions and warnings. WE reserves the right to make corrections, modifications, enhancements, improvements, and other changes to its products and services. WE DOES NOT WARRANT OR REPRESENT THAT ANY LICENSE, EITHER EXPRESS OR IMPLIED, IS GRANTED UNDER ANY PATENT RIGHT, COPYRIGHT, MASK WORK RIGHT, OR OTHER INTELLECTUAL PROPERTY RIGHT RELATING TO ANY COMBINATION, MACHINE, OR PROCESS IN WHICH WE PRODUCTS OR SERVICES ARE USED. INFORMATION PUBLISHED BY WE REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT CONSTITUTE A LICENSE FROM WE TO USE SUCH PRODUCTS OR SERVICES OR A WARRANTY OR ENDORSEMENT THEREOF. WE products are not authorized for use in safety-critical applications, or where a failure of the product is reasonably expected to cause severe personal injury or death. Moreover, WE products are neither designed nor intended for use in areas such as military, aerospace, aviation, nuclear control, submarine, transportation (automotive control, train control, ship control), transportation signal, disaster prevention, medical, public information network etc. Customers shall inform WE about the intent of such usage before design-in stage. In certain customer applications requiring a very high level of safety and in which the malfunction or failure of an electronic component could endanger human life or health, customers must ensure that they have all necessary expertise in the safety and regulatory ramifications of their applications. Customers acknowledge and agree that they are solely responsible for all legal, regulatory and safety-related requirements concerning their products and any use of WE products in such safety-critical applications, notwithstanding any applications-related information or support that may be provided by WE. CUSTOMERS SHALL INDEMNIFY WE AGAINST ANY DAMAGES ARISING OUT OF THE USE OF WE PRODUCTS IN SUCH SAFETYCRITICAL APPLICATIONS.

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ANS019 | Bipolar power supply and isolated signal transmission with MagI³C-FIMM 

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