Replacing Discrete Protection Components with Overvoltage Fault Protected...

TECHNICAL ARTICLE
Paul O’Sullivan
Applications Engineer,
Analog Devices, Inc.
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REPLACING DISCRETE
PROTECTION COMPONENTS
WITH OVERVOLTAGE FAULT
PROTECTED ANALOG SWITCHES
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Vs to VDD
Forward
Current
Flows
VDD
Forward
Current
Abstract
The challenge of designing robust electronic circuitry often results
in a design with a multitude of discrete protection components
with associated cost, design time, and space additions. This article
discusses fault protected switch architecture, along with the
performance benefits and other advantages it offers vs. traditional
discrete protection solutions. A new novel switch architecture and
proprietary high voltage process that provides industry-leading fault
protection along with the performance required for precision signal
chains is discussed. ADI’s new portfolio of fault protected switches
and multiplexers (ADG52xxF and ADG54xxF) use this technology.
Analog input protection for high performance signal chains is often a pain
point for system designers. There is typically a significant trade-off between
analog performance (such as leakage and on resistance) and the level of
protection that can be offered by discrete components.
Replacing the discrete protection components with overvoltage protected
switches and multiplexers can offer significant benefits in terms of analog
performance, robustness, and solution size. The overvoltage protected
component sits between sensitive downstream circuitry and the input that
is exposed to external stresses. An example of this would be the sensor
input terminal in a process control signal chain.
This article details the issues caused by overvoltage events, discusses
traditional discrete protection solutions and the associated drawbacks,
presents the solution offered by overvoltage protected analog switches
including features and system benefits, and finally introduces the industryleading portfolio of ADI fault protected analog switches.
Overvoltage Issues—Back to Basics
When the input signal applied to a switch exceeds the power supplies
(VDD or VSS) by more than a diode drop, the ESD protection diodes within
the IC become forward-biased and current flows from the input signal to
the supplies, as shown in Figure 1. This current could damage the part
and may trigger a latch-up event if the current is not limited.
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Internal ESD
Protection
of Switch
Load
Current
S
D
RS
RL
VS
VCC
GND
VSS
Figure 1. Overvoltage current path.
If the switch is unpowered, there are a couple of scenarios that could occur:
1. If the power supplies are floating, the input signal could end up
powering the VDD rail through the ESD diodes. In that case, the VDD pin
goes to within a diode drop of the input signal. This means the switch
would effectively be powered, as would any other components using
the same VDD rail. This could lead to unknown and uncontrolled operation
of devices in the signal chain.
2. If the power supplies are grounded, the PMOS device will turn on with
negative VGS so the switch will pass a clipped signal to the output,
possibly damaging downstream components that would also be
unpowered (see Figure 2). Note: if there are diodes to the supply, they
will forward bias and clip the signal to +0.7 V.
OV
OV
OV
PMOS turns on with negative VGS
PMOS is ON so signal passes through to output
Figure 2. Overvoltage signal with power supply grounded.
2
Replacing Discrete Protection Components with Overvoltage Fault Protected Analog Switches
+15 V
±10 V
0 to10 V
0 to 5 V
±5 V
4 mA to 20 mA
0 mA to 20 mA
2 kΩ
VIN1
–15 V
+15 V
Mux
PGIA
Funnel
Amp
Serial Interface
16-Bit to 24-Bit ADC
4
2 kΩ
VIN8
–15 V
Figure 3. Discrete protection solution.
Discrete Protection Solution
Designers traditionally solve input protection issues with discrete protection
components.
There may still be a requirement for an external TVS or a smaller current
limiting resistor for more stringent cases such as IEC ESD (IEC 61000-4-2),
EFT, or surge protection.
Fault Switch
Large series resistors are used to limit the current during a fault, and Schottky
or Zener diodes to the supply rails clamp any overvoltage signals. An example
of such a protection scheme in a multiplexed signal chain is shown in Figure 3.
However, there are many disadvantages to using these discrete protection
components.
Input
3. There will be no protection in the floating supply condition as the ESD
diodes to the supplies won’t provide any clamping protection.
Traditional Switch Architecture
The diagram in Figure 4 gives an overview of a traditional switch architecture.
The switch component (on the right hand side of Figure 4) has ESD diodes
to each of the supply rails, at both the input and output side of the switch
element. The external discrete protection components are shown here as
well—the series resistor for current limiting and the Schottky diodes to
the supplies for overvoltage clamping. There is often a requirement for a
bidirectional TVS for additional protection in harsher environments.
Overvoltage
Protection
Switch
Output to
Downstream
Currents
GND
VSS
GND
Figure 5. Fault protected switch architecture.
In the case of an overvoltage condition at one of the switch inputs, the
affected channel turns off and the input goes high impedance. The leakage will remain low on the other channels, so the remaining channels can
continue to operate as normal with minimal impact on performance. This
allows for very little compromise between system speed/performance and
overvoltage protection.
The fault protected switch can therefore greatly simplify the signal chain
solution. The switch overvoltage protection removes the requirement for the
current limiting resistors and Schottky diodes in many cases. The overall
system performance is no longer limited by external discrete components
which typically introduce leakage and distortion into a signal chain.
ADI Fault Protected Switch Features
VDD
Input
Output to
Downstream
Currents
Bidirectional
ESD Cell
1. The series resistor will increase the settling time of the multiplexer and
slow down the overall settling time.
2. The protection diodes will introduce additional leakage current and
varying capacitance that will impact the precision and linearity of the
measurement.
VDD
The new portfolio of fault protected switches from ADI are built on a
proprietary high voltage process that provides overvoltage protection up
to ±55 V in both the powered and unpowered states. These parts provide
industry-leading performance for fault protected switches for precision
signal chains.
NDMOS
PDMOS
P-Well
N-Well
VSS
Figure 4. Traditional switch architecture with external discrete protection.
Fault Protected Switch Architecture
The fault protected switch architecture is shown in Figure 5. The ESD
diodes at the input side are replaced with a bidirectional ESD cell, so the
input voltage range is no longer limited by the ESD diodes to the supply
rails. Therefore, the input can see voltages up to the limitation of the
process (which is ±55 V for the new fault protected switches from ADI).
The ESD diodes remain at the output side in most cases as there usually
isn’t a requirement for overvoltage protection from the output side.
The ESD cell at the input side can still provide excellent ESD protection.
The ADG5412F overvoltage fault protected quad SPST switch that uses
this type of ESD cell achieves a 5.5 kV HBM ESD rating.
Trench
Buried Oxide Layer
Handle Wafer
Figure 6. Trench isolated process.
Visit analog.com Latch-Up Immunity
The proprietary high voltage process is also trench isolated. An insulating
oxide layer is placed between NDMOS and the PDMOS transistors of each
switch. Parasitic junctions, which occur between the transistors in junctionisolated switches, are eliminated and the result is a switch that is latch-up
immune under all circumstances. The ADG5412F, for example, passes
a JESD78D latch-up test of ±500 mA for 1 second pulse width, which is
the most stringent test in the specification.
the ADG5404F design, the RON flatness is actually better even than the
ADG1404 (industry-leading low on resistance) and ADG5404 (latch-up
immune, but not overvoltage protected). In many applications, such as RTD
temperature measurements, the RON flatness is actually more important
than the absolute value of on resistance so the fault protected switch
provides potential for increased performance in these systems.
The typical fault mode for a low impedance system is for the drain output
to go open circuit in the case of a fault.
Analog Performance
High Impedance Systems
As well as achieving industry-leading robustness (overvoltage protection,
high ESD rating, known state at power-up without digital inputs present),
the new ADI fault protected switches also have industry-leading analog
performance. Switch performance as always is a trade off between low
on resistance and low capacitance/charge injection. The choice of switch
usually depends on whether the load is high impedance or low impedance.
Low leakage, low capacitance, low charge injection switches are most
commonly used in high impedance systems. Data acquisition systems are
typically high impedance due to amplifier loads on the multiplexer output.
Low on-resistance parts are usually used in low impedance systems,
where the on resistance of the switch needs to be kept to a minimum.
In low impedance systems, such as a power supply or gain stage, the on
resistance and source impedance in parallel with the load can cause gain
errors. Even though gain errors can be calibrated out in many cases, the
variation of on resistance (RON) across signal range or between channels
produces distortion that cannot be calibrated out. Therefore, low resistance
circuits are more subject to distortion errors due to RON flatness and RON
variation across channels.
The plot in Figure 7 shows the switch on resistance of one of the new fault
protected switches across the signal range. As well as achieving very low
on resistance, the RON flatness and matching between channels is also
excellent. The parts have a patented switch driver design that guarantees
a constant VGS voltage and delivers flat RON performance across the input
voltage range. The trade-off is a slightly reduced signal range where
optimal performance can be achieved, which can be seen from the shape
of the RON plots. There can be significant system benefits because of this
RON performance in applications sensitive to RON variation or THD.
40
VDD = +15 V
VSS = –15 V
35
On Resistance (Ω)
30
Leakage is the dominant source of error in high impedance circuits.
Any leakage currents can lead to significant measurement errors.
XX
Low capacitance and low charge injection is also critical for faster
settling. This allows for maximum data throughput in a data
acquisition system.
The leakage performance of the new ADI fault protected switches is
excellent. In normal operation the leakage current is in the low nA range,
which is critical for accurate measurements in many applications.
Critically, the leakage performance is also very good even when one of the
input channels is in fault. This means that measurements can continue on
other channels until the fault is fixed, thereby reducing system downtime.
The overvoltage leakage current for the ADG5248F 8:1 multiplexer is
shown in Figure 8.
The typical fault mode for a high impedance system is for the drain output
to pull to the supply rail in the case of a fault.
6
VDD = +15 V
VSS = –15 V
5
Leakage Current (nA)
Low Impedance Systems
XX
4
3
2
VS = –30 V
VS = +30 V
VS = –55 V
VS = +55 V
1
25
20
0
+125°C
15
+85°C
10
20
40
60
80
Temperature (°C)
100
120
Figure 8. ADG5248F overvoltage leakage current vs. temperature.
+25°C
–40°C
5
0
Fault Diagnostics
Figure 7. Fault protected switch on resistance.
Most of the new ADI fault protected switches also feature digital fault pins.
The FF pin is a general fault flag, which indicates that one of the input
channels is in fault. The specific fault pin (or SF pin) is a pin that can be
used to debug which specific input is in fault.
The ADG5404F is the new latch-up immune, overvoltage fault protected
multiplexer. Latch-up immune parts and overvoltage protected parts
typically have higher on resistance and worse on-resistance flatness
than standard parts. However, due to the constant VGS scheme used in
These pins can be useful for fault diagnostics in a system. The FF pin
first alerts a user to a fault. The user can then cycle through the digital
inputs and the SF pin will identify which particular switch or switches
are in fault.
0
–15
–12
–9
–6
–3
0
3
6
9
12
15
VS, VD (V)
3
4
Replacing Discrete Protection Components with Overvoltage Fault Protected Analog Switches
System Benefits
such as RTD or thermocouple temperature sensors, pressure sensors,
and humidity sensors. In a process control application, the sensor may be
connected at the end of a very long cable in a factory, with the potential
for faults along the length of the cable.
The system benefits of the new portfolio of fault protected switches are
captured in Figure 9. The benefits to a system designer are great, both in
terms of ensuring optimal analog performance in a precision signal chain,
and in terms of system robustness.
Features
System Benefits
Fault Protection
±55 V Overvoltage Protection
Prevents damage to downstream circuitry
Reduces the need for discrete
protection components
Fault Detection
Digital Output Indicator
for Fault Conditions
Alerts to source of fault
Eliminates the need for complex fault
detection software routines
High ESD
Industry-Leading 5.5 kV HBM ESD
Eases board assembly
Reduces ESD components
Precision Performance
Low RON and RON Flatness
Low Leakage Current
Prevents signal distortion
Maximizes system performance
The multiplexer in this case is the ADG5249F, which is optimized for low
capacitance and low leakage. Low leakage is important for these type of
small signal sensor measurements.
The switch operates off ±15 V supplies, while the secondary fault supplies
are configured for 5 V and GND to protect the downstream PGA and ADC.
The main sensor signal passes through the multiplexer to the PGA and
ADC while the fault diagnostics are sent directly to the microcontroller
to provide an interrupt in the case of a fault. The user can therefore be
alerted to a fault condition and can determine which of the sensors is in
fault. A technician can then be sent out to debug the fault and if necessary
replace the sensor or cable in fault.
Because of the industry-leading low fault leakage specification, the other
sensors can continue to be monitored even while one of the sensors is
down and awaiting replacement. Without such low fault leakage, a fault
on one channel could make all of the other channels unusable until the
fault was repaired.
Figure 9. ADI fault protected switch—features and system benefits.
The benefits compared to discrete protection components are obvious
and have been described in detail already. The proprietary high voltage
process and novel switch architecture also gives the new range of ADI fault
protected switches a number of advantages over competitor solutions.
XX
Industry-leading RON flatness for precision measurements
XX
Industry-leading fault leakage current to allow for continued operation on
other channels not affected by a fault (10× better than competing solutions)
XX
Parts with secondary fault supplies for precision fault thresholds while
still maintaining optimum analog switch performance
XX
Intelligent fault flags for system fault diagnostics
The second application example in Figure 11 is a portion of a data
acquisition signal chain where the ADG5462F channel protector would
add value. In this case there is a PGA with ±15 V supply rails, while the
ADC downstream has as input signal range of 0 V to 5 V.
The channel protector sits between the PGA and ADC. It uses the ±15 V
supply rails as its primary supplies to achieve optimum on resistance, and
uses 0 V and 5 V for its secondary supply rails. The ADG5462F will allow
the signal to pass through in normal operation, but will clamp any overvoltage outputs from the PGA to between 0 V and 5 V to protect the ADC.
Therefore, like the previous applications example, the signal of interest is
biased in the flat RON region of operation.
Application Examples
This first application example shown in Figure 10 is a process control
signal chain, where a microcontroller is monitoring a number of sensors
VDD +15 V
Analog Diagnostics
PosFV +5 V
S1A
Sensor
ADG5249F
Dual 4:1 Mux
S4A
S1B
PGA
ADC
Sensor
NegFV 0 V
DC
Overvoltage
Fault
S4B
Fault Flag and
Specific Flag
Diagnostics
VSS —15 V
Figure 10. Process control application example.
+15 V
—15 V
+5 V
GND
VDD VSS
PosFV
NegFV
VIN
+5 V
PGA
ADC
+5 V
Figure 11. Data acquisition application example.
Data
Microcontroller
Visit analog.com Portfolio Summary
Table 1. Low On-Resistance Family of Fault Protected Switches
Product
ADG5412F
ADG5413F
ADG5412BF
ADG5413BF
ADG5462F
ADG5404F
ADG5436F
Configuration
Fault Trigger Threshold
Output Fault Mode
Fault Flag
Quad SPST
Primary supplies
Open circuit
General flag
Primary supplies
Open circuit
General flag
Secondary supplies
Primary supplies
Primary supplies
Pull to secondary supply or open circuit (default)
Pull to secondary supply or open circuit (default)
Pull to secondary supply or open circuit (default)
General flag
General and specific flags
General and specific flags
Quad SPST and
bidirectional OVP
Quad-channel protector
4:1 mux
Dual SPDT
Table 2. Low Capacitance/Low Charge Injection Family of Fault Protected Switches
Product
ADG5208F
ADG5209F
ADG5248F
ADG5249F
ADG5243F
Configuration
8:1 multiplexer
Differential 4:1 multiplexer
8:1 multiplexer
Differential 4:1 multiplexer
Triple SPDT
Fault Trigger Threshold
Primary supplies
Primary supplies
Secondary supplies
Secondary supplies
Secondary supplies
Summary
Replacing traditional discrete protection components with overvoltage
protected switches and multiplexers can provide many system benefits in
a precision signal chain. As well as saving board space, the performance
benefits of replacing discrete components can be significant.
Analog Devices has a wide range of overvoltage protected switches and
multiplexers. The latest families of fault protected devices are listed in
Table 1 and Table 2. They are built on a proprietary high voltage and
latch-up immune process and provide industry-leading performance and
features for precision signal chains.
Output Fault Mode
Pull to rails
Pull to rails
Pull to secondary supplies
Pull to secondary supplies
Pull to secondary supplies
Fault Flag
None
None
General and specific flags
General and specific flags
General and specific flags
About the Author
Paul O’Sullivan is an applications engineer in ADI’s Linear and
Precision Technology business unit in Limerick, Ireland. He supports
the switch/multiplexer product portfolio and previously supported
the power management portfolio for ADI. He joined ADI in 2004 with
a bachelor’s degree in electrical and electronic engineering from
University College Cork and an M.Eng. from University of Limerick.
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