Switch and Multiplexer Design Considerations for Hostile Environments

Switch and Multiplexer Design Considerations
for Hostile Environments
By Michael Manning
Introduction
Hostile environments found in automotive, military, and avionic applications
push integrated circuits to their technological limits, requiring them to withstand high voltage and current, extreme temperature and humidity, vibration,
radiation, and a variety of other stresses. Systems engineers are rapidly
adopting high performance electronics to provide features and functions
in application areas such as safety, entertainment, telematics, control, and
human-machine interfaces. The increased use of precision electronics comes
at the price of higher system complexity and greater vulnerability to electrical
disturbances including overvoltages, latch-up conditions, and electrostatic
discharge (ESD) events. Because electronic circuits used in these applications
require high reliability and high tolerance to system faults, designers must
consider both the environment and the limitations of the components that
they choose.
Figure 1. Standard analog switch circuitry.
The source, drain, and logic terminals include clamping diodes to the supplies
to provide ESD protection, as illustrated in Figure 1. Reverse-biased in normal
operation, the diodes do not pass current unless the signal exceeds the supINVERTER
V DD
V DD
SOURCE
Standard Analog Switch Architecture
To fully understand the effects of fault conditions on an analog switch, we
must first look at its internal structure and operational limits.
A standard CMOS switch (Figure 1) uses both N- and P-channel MOSFETs
for the switch element, digital control logic, and driver circuitry. Connecting
N- and P-channel MOSFETs in parallel permits bidirectional operation, allowing
the analog input voltage to extend to the supply rails, while maintaining fairly
constant on resistance over the signal range.
DRAIN I/O
NMOS
V SS
V DD
In addition, manufacturers specify absolute maximum ratings for every
integrated circuit; these ratings must be observed in order to maintain reliable operation and meet published specifications. When absolute maximum
ratings are exceeded, operational parameters cannot be guaranteed; and
even internal protections against ESD, overvoltage, or latch-up can fail,
resulting in device (and potentially further) damage or failure.
This article describes challenges engineers face when designing analog
switches and multiplexers into modules used in hostile environments and
provides suggestions for general solutions that circuit designers can use to
protect vulnerable parts. It also introduces some new integrated switches
and multiplexers that provide increased overvoltage protection, latch-up
immunity, and fault protection to deal with common stress conditions.
PMOS
V SS
INPUT
BUFFER
DIGITAL
INPUT
DRIVER
GND
ply voltage. The diodes vary in size, depending on the process, but they are
generally kept small to minimize leakage current in normal operation.
The analog switch is controlled as follows: the N-channel device is on for
positive gate-to-source voltages and off for negative gate-to-source voltages; the P-channel device is switched by the complementary signal, so
it is on at the same time as the N-channel device. The switch is turned on
and off by driving the gates to opposite supply rails.
With a fixed voltage on the gate, the effective drive voltage for either transistor varies in proportion to the polarity and magnitude of the analog signal
passing through the switch. The dashed lines in Figure 2 show that when the
input signal approaches the supplies, the channel of one device or the other
will begin to saturate, causing the on resistance of that device to increase
sharply. The parallel devices compensate for one another in the vicinity of the
rail voltages, however, so the result is a fully rail-to-rail switch, with relatively
constant on resistance over the signal range.
www.analog.com
Voltage limitations that apply to the analog switch inputs—with and without
power supplies—are often due to the ESD protection circuitry, which may
fail as a result of fault conditions.
P-CHANNEL RON
N-CHANNEL RON
RON ( )
VDD
COMBINED RESISTANCE
OF PMOS AND
NMOS FETs.
VDD
SOURCE I/O
DRAIN I/O
VSS
VSS
Figure 4. Analog switch—ESD protection diodes.
V SOURCE (V)
Figure 2. Standard analog switch RON graph.
Absolute Maximum Ratings
Switch power requirements, specified in the device data sheet, should be
followed in order to guarantee optimal performance, operation, and lifetime.
Unfortunately, power supply failures, voltage transients in harsh environments, and system or user faults that occur in the course of real-world
operation may make it impossible to meet data sheet recommendations
consistently.
Whenever an analog switch input voltage exceeds the supplies, the internal
ESD protection diodes become forward-biased, allowing large currents to
flow, even if the supplies are turned off, causing ratings to be exceeded.
When forward-biased, the diodes are not rated to pass currents greater
than a few tens of milliamperes; they can be damaged if this current is not
limited. Furthermore, the damage caused by a fault is not limited to the
switch but can also affect downstream circuitry.
The Absolute Maximum Ratings section of a data sheet (Figure 3) describes
the maximum stress conditions a device can tolerate; it is important to note
that these are stress ratings only. Exposure to absolute maximum ratings
conditions for extended periods may affect device reliability. The designer
should always follow good engineering practice by building margin into the
design. The example here is from a standard switch/multiplexer data sheet.
Figure 3. Absolute Maximum Ratings section of a data sheet.
Analog and digital input voltage specifications are limited to 0.3 V beyond
VDD and VSS, while digital input voltages are limited to 0.3 V beyond VDD
and ground. When the analog inputs exceed the supplies, the internal
ESD protection diodes become forward-biased and begin to conduct. As
stated in the Absolute Maximum Ratings section, overvoltages at IN, S, or
D are clamped by internal diodes. While currents exceeding 30 mA can
be passed through the internal diodes without any obvious effects, device
reliability and lifetime may be reduced, and the effects of electromigration,
the gradual displacement of metal atoms in a conductor, may be seen over
time. As heavy current flows through a metal path, the moving electrons
interact with metal ions in the conductor, forcing atoms to move with the
flow of electrons. Over time this can lead to open or short circuits.
When designing a switch into a system, it is important to consider potential
faults that may occur in the system due to component failure, user error, or
environmental effects. The next section will discuss how fault conditions
that exceed the absolute maximum ratings of a standard analog switch can
damage the switch or cause it to malfunction.
Common Fault Conditions, System Stresses, and Protection Methods
Fault conditions can occur for many different reasons; some of the most
common system stresses and their real-world sources are shown in Table 1.
Table 1.
Fault Type
Fault Causes
Overvoltage
• Loss of power
• System malfunction
• Hot swap connects and disconnects
• Power-supply sequencing issues
• Miswiring
• User error
Latch-Up
• Overvoltage conditions (as listed above)
• Exceeding process ratings
• SEU (single event upsets)
ESD
• Storage/assembly
• PCB assembly
• User operation
Some stress may not be preventable. Regardless of the source of the stress,
the more important issue is how to deal with its effects. The questions and
answers below cover these fault conditions: overvoltages, latch-up, and
ESD events—and some common methods of protection.
In this example, the VDD to VSS parameter is rated at 18 V. The rating is
determined by the switch’s manufacturing process and design architecture.
Any voltage higher than 18 V must be completely isolated from the switch,
or the intrinsic breakdown voltages of elements associated with the process
will be exceeded, which may damage the device and lead to unreliable
operation.
| Switch and Multiplexer Design Considerations for Hostile Environments
2
Overvoltage
T
What Is an Overvoltage Condition?
Overvoltage conditions occur when analog or digital input conditions exceed
the absolute maximum ratings. The following three examples highlight some
common issues designers need to consider when using analog switches.
1. Loss of Power with Signals Present on Analog Inputs (Figure 5)
VDD = 0V
1
In some applications, the power supply to a module is lost, while input signals
from remote locations may still be present. When power is lost, the power
supply rails may go to ground—or one or more may float. If the supplies go
to ground, the input signals can forward-bias the internal diode, and current
from the switch input will flow to ground—damaging the diode if the current
is not limited.
GND = 0V
±5V INPUT
DRAIN OUTPUT:
CLIPPED SIGNAL
SOURCE INPUT:
±5V SINE WAVE
CH1 2.00V
V DD
V S > V DD
FORWARD
CURRENT
FLOWS
SWITCH
SIGNAL
RANGE
CLIPPING
CH2 100mV
M200𝛍s
T
–36.0𝛍s
A CH1
3.00V
Figure 7. Clipping.
LOAD
CURRENT
FORWARD
CURRENT
S
D
RS
RL
VS
GND
V SS
Figure 5. Fault paths.
If loss of power causes the supplies to float, the input signals can power the
part through the internal diodes. As a result, the switch—and possibly any
other components running from its VDD supply—may be powered up.
What’s the Best Way to Deal with Overvoltage Conditions?
The three examples above are the results of analog inputs exceeding a
supply—VDD, VSS, or GND. Simple protection methods to counter these
conditions include the addition of external resistors, Schottky diodes to
the supplies, and blocking diodes on the supplies.
Resistors, to limit current, are placed in series with any switch channel
that is exposed to external sources (Figure 8). The resistance must be high
enough to limit the current to approximately 30 mA (or as specified by the
absolute maximum ratings). The obvious downside is the increase in
RON, ∆RON, per channel, and ultimately the overall system error. Also, for
applications using multiplexers, faults on the source of an off channel can
appear at the drain, creating errors on other channels.
VDD
2. Overvoltage Conditions on Analog Inputs
When analog signals exceed the power supplies (VDD and VSS), the
supplies can be pulled to within a diode drop of the fault signal. Internal
diodes become forward-biased and currents flow from the input signal
to the supplies. The overvoltage signal can also pass through the switch
and damage parts downstream. The explanation for this can be seen by
considering the P-channel FET (Figure 6).
0V
0V
0V
Figure 6. FET switch.
A P-channel FET requires a negative gate-to-source voltage to turn it on.
With the switch gate equal to VDD, the gate-to-source voltage is positive,
so the switch is off. In an unpowered circuit, with the switch gate at 0 V
or where the input signal exceeds VDD, the signal will pass through the
switch—as there is now a negative gate-to-source voltage.
3. Bipolar Signals Applied to a Switch Powered from a Single Supply
This situation is similar to the previously described overvoltage condition.
The fault occurs when the input signal goes below ground, causing the
diode from the analog input to ground to forward-bias and current to flow.
When an ac signal, biased at 0 V dc, is applied to the switch input, the
parasitic diodes can be forward-biased for some portion of the negative
half cycle of the input waveform. This happens if the input sine wave goes
below approximately –0.6 V, turning the diode on and clipping the input
signal, as shown in Figure 7.
S
D
RL
GND
GND
VSS
Figure 8. Resistor-diode protection network.
Schottky diodes connected from the analog inputs to the supplies provide
protection, but at the expense of leakage and capacitance. The diodes work
by preventing the input signal from exceeding the supply voltage by more
than 0.3 V to 0.4 V, ensuring that the internal diodes do not forward-bias
and current does not flow. Diverting the current through the Schottky diodes
protects the device, but care must be taken not to overstress the external
components.
A third method of protection involves placing blocking diodes in series with
the supplies (Figure 9), blocking current flow through the internal diodes.
Faults on the inputs cause the supplies to float, and the most positive and
negative input signals become the supplies. As long as the supplies do not
exceed the absolute maximum ratings of the process, the device should
tolerate the fault. The downside to this method is the reduced analog signal
range due to the diodes on the supplies. Also, signals applied to the inputs
may pass through the device and affect downstream circuitry.
www.analog.com | 3
VDD
VSS
PMOS
S
NMOS
D
VS
NMOS
PMOS
RL
VDD
Figure 9. Blocking diodes in series with supplies.
While these protection methods have advantages and disadvantages, they all
require external components, extra board area, and additional cost. This can
be especially significant in applications with high channel count. To eliminate
the need for external protection circuitry, designers should look for integrated
protection solutions that can tolerate these faults. Analog Devices offers a
number of switch/mux families with integrated protection against power off,
overvoltage, and negative signals.
What Prepackaged Solutions Are Available?
The ADG4612 and ADG4613 from Analog Devices offer low on resistance
and distortion, making them ideal for data acquisition systems requiring
high accuracy. The on resistance profile is very flat over the full analog
input range, ensuring excellent linearity and low distortion.
The ADG4612 family offers power-off protection, overvoltage protection,
and negative signal handling, all conditions a standard CMOS switch
cannot handle.
When no power supplies are present, the switch remains in the off condition.
The switch inputs present a high impedance, limiting current flow that could
damage the switch or downstream circuitry. This is very useful in applications
where analog signals may be present at the switch inputs before the power is
turned on, or where the user has no control over the power supply sequence.
In the off condition, signal levels up to 16 V are blocked. Also, the switch turns
off if the analog input signal level exceeds VDD by VT.
SX
DX
OV
MONITOR
DIGITAL
INPUT
VDD
Figure 11. High voltage fault-protected switch architecture.
VSS
GND
VSS
PS
MONITOR
These devices comprise N-channel, P-channel, and N-channel MOSFETs
in series, as illustrated in Figure 11. When one of the analog inputs or
outputs exceeds the power supplies, one of the MOSFETs switches off, the
multiplexer input (or output) appears as an open circuit, and the output is
clamped to within the supply rail, thereby preventing the overvoltage from
damaging any circuitry following the multiplexer. This protects the multiplexer, the circuitry it drives, and the sensors or signal sources that drive
the multiplexer. When the power supplies are lost (through, for example,
battery disconnection or power failure) or momentarily disconnected (rack
system, for example), all transistors are off and the current is limited to
subnanoampere levels. The ADG508F, ADG509F, and ADG528F include 8:1
and differential 4:1 multiplexers with such functionality.
The ADG465 single and ADG467 octal channel protectors have the same
protective architecture as these fault-protected multiplexers, without the
switch function. When powered, the channel is always in the on condition, but in the event of a fault, the output is clamped to within the supply
voltages.
Latch-Up
What Is a Latch-Up Condition?
Latch-up may be defined as the creation of a low impedance path between
power supply rails as a result of triggering a parasitic device. Latch-up
occurs in CMOS devices: intrinsic parasitic devices form a PNPN SCR
structure when one of the two parasitic base emitter junctions is momentarily forward-biased (Figure 12). The SCR turns on, causing a continuing
short between the supplies. Triggering a latch-up condition is serious: in the
“best” case, it leads to device malfunction, with power cycling required to
restore the device to normal operation; in the worst case, the device (and
possibly power supply) can be destroyed if current flow is not limited.
(a)
VDD
I/O
I/O
I/O
I/O
VSS/GND
N+
P+
P+
N+
N+
P+
RW
Q1
Q2
N-WELL
SX
DX
INX
RS
VDD
P– SUBSTRATE
Figure 10. ADG4612/ADG4613 switch architecture.
Figure 10 shows a block diagram of the family’s power-off protection
architecture. Switch source and drain inputs are constantly monitored and
compared to the supply voltages, VDD and VSS. In normal operation the
switch behaves as a standard CMOS switch with full rail-to-rail operation.
However, during a fault condition, where the source or drain input exceeds a
supply by a threshold voltage, internal fault circuitry senses the overvoltage
condition and puts the switch in isolation mode.
Analog Devices also offers multiplexers and channel protectors that can
tolerate overvoltage conditions of +40 V/–25 V beyond the supplies with
power (±15 V) applied to the device, and +55 V/–40 V unpowered. These
devices are specifically designed to handle faults caused by power-off
conditions.
I/O
VDD
RW
Q1
(b)
Q2
RS
VSS/GND
I/O
Figure 12. Parasitic SCR structure: a) device b) equivalent circuit.
The fault and overvoltage conditions described earlier are among the common causes of triggering a latch-up condition. If signals on the analog or
digital inputs exceed the supplies, a parasitic transistor is turned on. The
collector current of this transistor causes a voltage drop across the base
| Switch and Multiplexer Design Considerations for Hostile Environments
4
emitter of a second parasitic transistor, which turns the transistor on, and
results in a self-sustaining path between the supplies. Figure 12(b) clearly
shows the SCR circuit structure formed between Q1 and Q2.
Events need not last long to trigger latch-up. Short-lived transients, spikes,
or ESD events may be enough to cause a device to enter a latch-up state.
Latch-up can also occur when the supply voltages are stressed beyond the
absolute maximum ratings of the device, causing internal junctions to break
down and the SCR to trigger.
The second triggering mechanism occurs if a supply voltage is raised
enough to break down an internal junction, injecting current into the SCR.
What’s the Best Way to Deal with Latch-Up Conditions?
Protection methods against latch-up include the same protection methods
recommended to address overvoltage conditions. Adding current-limiting
resistors in the signal path, Schottky diodes to the supplies, and diodes in
series with the supplies—as illustrated in Figure 8 and Figure 9—all help to
prevent current from flowing in the parasitic transistors, thereby preventing
the SCR from triggering.
Switches with multiple supplies may have additional power-supply sequencing
issues that may violate the absolute maximum ratings. Improper supply
sequencing can lead to internal diodes turning on and triggering latch-up.
External Schottky diodes, connected between supplies, will adequately prevent
SCR conduction by ensuring that when multiple supplies are applied to the
switch, VDD is always within a diode drop (0.3 V for Schottky) of these supplies,
thereby preventing violation of the maximum ratings.
What Prepackaged Solutions Are Available?
As an alternative to using external protection, some ICs are manufactured
using a process with an epitaxial layer, which reduces the substrate resistance in the SCR structure. The lower resistance means that a harsher
stress is required to trigger the SCR, resulting in a device that is less
susceptible to latch-up. An example is the Analog Devices iCMOS® process, which made possible the development of the ADG121x, ADG141x,
and ADG161x switch/mux families.
For applications requiring a latch-up proof solution, new trench-isolated
switches and multiplexers guarantee latch-up prevention in high voltage
industrial applications operating at up to ±20 V. The ADG541x and ADG521x
families are designed for instrumentation, automotive, avionics, and other
harsh environments that are likely to foster latch-up. The process uses
an insulating oxide layer (trench) placed between the N-channel and the
P-channel transistors of each CMOS switch. The oxide layers, both horizontal and vertical, produce complete isolation between devices. Parasitic
junctions between transistors in junction-isolated switches are eliminated,
resulting in a completely latch-up proof switch.
I/O
T
R
E
N
C
H
P+
N–
VG
I/O
P-CHANNEL
P+
VG
I/O
T
R
E
N
C
H
N+
N-CHANNEL
P–
T
R
E
N
C
H
BURIED OXIDE LAYER
SUBSTRATE (BACKGATE)
Figure 13. Trench isolation in latch-up prevention.
The industry practice is to classify the susceptibility of inputs and outputs
to latch-up in terms of the amount of excess current an I/O pin can source
or sink in the overvoltage condition before the internal parasitic resistances
develop enough voltage drop to sustain the latch-up condition.
ESD—Electrostatic Discharge
What Is an Electrostatic Discharge Event?
Typically the most common type of voltage transient that a device is exposed
to, ESD, can be defined as a single, fast, high current transfer of electrostatic
charge between two objects at different electrostatic potentials. We frequently
experience this after walking across an insulating surface, such as a rug,
storing a charge, and then touching an earthed piece of equipment—resulting
in a discharge through the equipment, with high currents flowing in a short
space of time.
ICs can be damaged by the high voltages and high peak currents generated
by an ESD event. The effects of an ESD event on an analog switch can include
reduced reliability over time, the degradation of switch performance,
increased channel leakage, or complete device failure.
ESD events can occur at any stage of the life of an IC, from manufacturing
through testing, handling, OEM user, and end-user operation. In order to
evaluate an IC’s robustness to various ESD events, electrical pulse circuits
modeling the following simulated stress environments were identified: human
body model (HBM), field-induced charged device model (FICDM), and machine
model (MM).
What’s the Best Way to Deal with ESD Events?
ESD prevention methods, such as maintaining a static safe work area, are
used to avoid any buildup during production, assembly, and storage. These
environments, and the individuals working in them, can generally be carefully controlled, but the environments in which the device later finds itself
may be anything but controlled.
Analog switch ESD protection is generally in the form of diodes from the
analog and digital inputs to the supplies, as well as power supply protection
in the form of diodes between the supplies—as illustrated in Figure 14.
ANALOG INPUT
PROTECTION
DIGITAL INPUT
PROTECTION
V DD
S
VL
D
V SS
POWER SUPPLY
PROTECTION
V DD
V DD
V SS
V SS
GND
IN
GND
Figure 14. Analog switch ESD protection.
I/O
N+
A value of 100 mA is generally considered adequate. Devices in the ADG5412
latch-up proof family were stressed to ±500 mA with a 1 ms pulse without
failure. Latch-up testing at Analog Devices is performed according to
EIA/JEDEC-78 (IC Latch-Up Test).
The protection diodes clamp voltage transients and divert current to the
supplies. The downside of these protection devices is that they add capacitance and leakage to the signal path in normal operation, which may be
undesirable in some applications.
For applications that require greater protection against ESD events, discrete
components such as Zener diodes, metal oxide varistors (MOVs), transient
voltage suppressors (TVS), and diodes are commonly used. However, they
can lead to signal integrity issues due to the extra capacitance and leakage
on the signal line; this means design engineers need to carefully consider
the trade-off between performance and reliability.
What Prepackaged Solutions Are Available?
While the vast majority of ADI switch/mux products meet HBM levels of at
least ±2 kV, others go beyond this in robustness, achieving HBM ratings of
up to ±8 kV. ADG541x family members have achieved a ±8 kV HBM rating,
a ±1.5 kV FICDM rating, and a ±400 V MM rating, making them industry
leaders, combining high voltage performance and robustness.
www.analog.com | 5
Conclusion
When switch or multiplexer inputs come from remotely located sources,
there is an increased likelihood that faults can occur. Overvoltage conditions
may occur due to systems with poorly designed power-supply sequencing or
where hot-plug insertion is a requirement. In harsh electrical environments,
transient voltages due to poor connections or inductive coupling may damage
components if not protected. Faults can also occur due to power-supply failures where power connections are lost while switch inputs remain exposed
to analog signals. Significant damage may result from these fault conditions,
possibly causing damage and requiring expensive repairs. While a number of
protective design techniques are used to deal with faults, they add extra cost
and board area and often require a trade-off in switch performance; and even
with external protection implemented, downstream circuitry is not always
protected. Since analog switches and multiplexers are often a module’s
most likely electronic components to be subjected to a fault, it is important
to understand how they behave when exposed to conditions that exceed the
absolute maximum ratings.
Ultimately, using switches with fault protection, overvoltage protection,
immunity to latch-up, and a high ESD rating yields a robust product
that meets industry regulations and enhances customer and end-user
satisfaction.
Michael Manning ([email protected])
graduated from National University of Ireland, Galway,
with a BSc in applied physics and electronics. In 2006,
he joined Analog Devices as an applications engineer
in the switch/multiplexer group in Limerick, Ireland.
Previously, Michael spent five years as a design and
applications engineer in the automotive division at
ALPS Electric in Japan and Sweden.
Switch/mux products, like devices mentioned here, are available with
integrated protection, allowing designers to eliminate external protection
circuitry, reducing the number and cost of components in board designs.
Savings are even more significant in applications with high channel count.
| Switch and Multiplexer Design Considerations for Hostile Environments
6
Appendix
Analog Devices Switch/Multiplexer Protection Products
High Voltage Latch-Up Proof Switches
Part
Number
Configuration
Number of Switch
Functions
RON
(𝛀)
Max Analog
Signal Range
Charge
Injection (pC)
On Leakage
@ 85°C (nA)
ADG5212
SPST/NO
4
160
VSS to VDD
0.07
0.25
ADG5213
SPST/NO-NC
4
160
VSS to VDD
0.07
0.25
ADG5233
SPST/NO-NC
3
160
VSS to VDD
0.6
0.3
ADG5234
SPST/NO-NC
4
160
VSS to VDD
0.6
0.3
ADG5236
SPST/NO-NC
2
160
VSS to VDD
0.6
0.4
ADG5412
SPST/NO
4
9
VSS to VDD
240
2
ADG5413
SPST/NO-NC
4
9
VSS to VDD
240
2
ADG5433
SPST/NO-NC
3
13.5
VSS to VDD
130
4
ADG5434
SPST/NO-NC
4
13.5
VSS to VDD
130
4
ADG5436
SPST/NO-NC
2
9
VSS to VDD
200
2
Supply Voltages (V)
Packages
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
Price @ 1k
($U.S.)
2.18
2.18
2.15
2.15
2.26
2.18
2.18
2.15
TSSOP
3.04
LFCSP,
TSSOP
2.26
High Voltage Latch-Up Proof Multiplexers
Part
Number
Switch/Mux
Function × #
RON
(𝛀)
Max Analog
Signal Range
Charge
Injection (pC)
ADG5204
(4:1) × 1
160
VSS to VDD
0.6
30
0.5
ADG5208
(8:1) × 1
160
VSS to VDD
0.4
58
0.5
ADG5209
(4:1) × 2
160
VSS to VDD
0.4
31
0.5
ADG5408
(8:1) × 1
13.5
VSS to VDD
115
133
4
ADG5409
(4:1) × 2
13.5
VSS to VDD
115
81
4
ADG5404
(4:1) × 1
9
VSS to VDD
220
132
2
On Capacitance On Leakage
(pF)
@ 85°C (nA)
Supply Voltages (V)
Packages
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
Dual (±15), dual (±20),
single (+12), single (+36)
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
LFCSP,
TSSOP
Price @ 1000
to 4999 ($U.S.)
2.26
2.41
2.41
2.41
2.41
2.26
Low Voltage Fault-Protected Multiplexers
Part
Number
ADG4612
ADG4613
Configuration
SPST/NO
SPT/NO-NC
Number of Switch
Functions
4
4
Max Analog
Signal Range
–5.5 V to VDD
–5.5 V to VDD
Fault Response
Time (ns)
295
295
Fault Recovery
Time (𝛍s)
1.2
1.2
–3 dB Bandwidth
(MHz)
Packages
Price @ 1k
($U.S.)
293
294
TSSOP
LFCSP, TSSOP
1.84
1.84
High Voltage Fault-Protected Multiplexers
Part
Number
Switch/Mux
Function × #
RON
(𝛀)
Max Analog Signal Range
tTRANSITION
(ns)
Supply Voltages (V)
Power Dissipation
(mW)
Packages
Price @ 1000 to
4999 ($U.S.)
ADG438F
(8:1) × 1
400
VSS + 1.2 V to VDD – 0.8 V
170
Dual (±15)
2.6
DIP, SOIC
3.68
ADG439F
ADG508F
ADG509F
ADG528F
(4:1) × 2
(8:1) × 1
(4:1) × 2
(8:1) × 1
400
300
300
300
VSS + 1.2 V to VDD – 0.8 V
VSS + 3 V to VDD – 1.5 V
VSS + 3 V to VDD – 1.5 V
VSS + 3 V to VDD – 1.5 V
170
200
200
200
Dual (±15)
Dual (±12), dual (±15)
Dual (±12), dual (±15)
Dual (±12), dual (±15)
2.6
3
3
3
DIP, SOIC
DIP, SOIC
DIP, SOIC
DIP, LCC
3.68
3.31
3.31
3.91
High Voltage Channel Protectors
Part Number
ADG465
ADG467
Configuration
Channel protector
Channel protector
Number of Switch
Functions
1
8
RON (𝛀)
80
62
Max Positive
Supply (V)
20
20
Max Negative
Supply (V)
20
20
Packages
Price @ 1k
($U.S.)
SOIC, SOT
SOIC, TSSOP
0.84
2.40
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