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ISL54225_10 Datasheet, PDF (10/18 Pages) Intersil Corporation – High-Speed USB 2.0 (480Mbps) Multiplexer with Overvoltage Protection (OVP)
ISL54225
The HS1 channel switches are active (turned ON)
whenever the SEL voltage is logic “0”(Low) and the OE
voltage is logic “0”(Low).
The HS2 channel switches are active (turned ON)
whenever the SEL voltage is logic “1” (High) and the OE
voltage is logic “0” (Low).
OVERVOLTAGE PROTECTION (OVP)
The maximum normal operating signal range for the HSx
switches is from 0V to 3.6V. For normal operation, the
signal voltage should not be allowed to exceed these
voltage levels or go below ground by more than -0.3V.
However, in the event that a positive voltage > 3.8V
(typ) to 5.25V, such as the USB 5V VBUS voltage, gets
shorted to one or both of the COM+ and COM- pins or a
negative voltage < -0.5V (typ) to -5V gets shorted to one
or both of the COM pins, the ISL54225 has OVP circuitry
to detect the overvoltage condition and open the SPDT
switches to prevent damage to the USB down-stream
transceivers connected at the signal pins (HS1D-,
HS1D+, HS2D-, HS2D+).
The OVP and power-off protection circuitry allows the
COM pins (D-, D+) to be driven up to 5.25V while the
VDD supply voltage is in the range of 0V to 5.25V. In this
condition, the part draws < 100µA of ICOMx and IDD
current and causes no stress to the IC. In addition, the
SPDT switches are OFF and the fault voltage is isolated
from the other side of the switch.
External VDD Series Resistor to Limit IDD Current
during Negative OVP Condition
A 100Ω to 1kΩ resistor in series with the VDD pin (see
Figure 7) is required to limit the IDD current draw from the
system power supply rail during a negative OVP fault event.
With a negative -5V fault voltage at both COM pins, the
graph in Figure 8 shows the IDD current draw for
different external resistor values for supply voltages of
2.7V, 3.6V, and 5.25V. With a 500Ω resistor, the current
draw is limited to around 5mA. When the negative fault
voltage is removed, the IDD current will return to it’s
normal operation current of 25µA to 45µA.
The series resistor also provides improved ESD and
latch-up immunity. During an overvoltage transient
event (such as occurs during system level IEC 61000
ESD testing), substrate currents can be generated in
the IC that can trigger parasitic SCR structures to turn
ON, creating a low impedance path from the VDD
power supply to ground. This will result in a significant
amount of current flow in the IC, which can potentially
create a latch-up state or permanently damage the IC.
The external VDD resistor limits the current during this
over-stress situation and has been found to prevent
latch-up or destructive damage for many overvoltage
transient events.
Under normal operation, the low microamp IDD current
of the IC produces an insignificant voltage drop across
the series resistor resulting in no impact to switch
operation or performance.
-5V
FAULT
VOLTAGE
VSUPPLY
C
PROTECTION
RESISTOR
100Ω to 1kΩ
IDD
VDD
HSD1+
D+
HSD2+
OVP
D-
HSD1-
HSD2-
SEL LOGIC
OE
GND
FIGURE 7. VDD SERIES RESISTOR TO LIMIT IDD
CURRENT DURING NEGATIVE OVP AND
FOR ENHANCED ESD AND LATCH-UP
IMMUNITY
25
20
5.25V
15
VCOM+ = VCOM- = -5V
10
3.6V
5 2.7V
0
100 200 300 400 500 600 700 800 900 1k
RESISTOR (Ω)
FIGURE 8. NEGATIVE OVP IDD CURRENT vs
RESISTOR VALUE vs VSUPPLY
ISL54225 Operation
The following will discuss using the ISL54225 shown in
the “Application Block Diagram” on page 9.
POWER
The power supply connected at the VDD pin provides the
DC bias voltage required by the ISL54225 part for proper
operation. The ISL54225 can be operated with a VDD
voltage in the range of 2.7V to 5.25V.
For lowest power consumption you should use the lowest
VDD supply.
A 0.01µF or 0.1µF decoupling capacitor should be
connected from the VDD pin to ground to filter out any
power supply noise from entering the part. The
capacitor should be located as close to the VDD pin as
possible.
In a typical application, VDD will be in the range of
2.8V to 4.3V and will be connected to the battery or
LDO of the portable media device.
10
FN7627.0
July 2, 2010