MAX8586(2004) 查看數據表(PDF) - Maxim Integrated
零件编号
产品描述 (功能)
比赛名单
MAX8586 Datasheet PDF : 11 Pages
| |||
Single 1.2A USB Switch in
3mm x 3mm TDFN
Thermal Shutdown
When the MAX8586 die temperature exceeds +160°C,
the switch turns off and FAULT goes low. Thermal shut-
down does not utilize the 20ms fault-blanking timeout
period. When the junction temperature cools by 15°C,
the switch turns on again and FAULT returns high.
When an overload condition persists, the switch cycles
on and off, resulting in a pulsed output that reduces the
average system load.
Applications Information
Setting the Current Limit
A resistor from ISET to ground programs the current-
limit value. Use a resistor between 26kΩ and 60kΩ to
set the current limit according to the formula:
ILIM(TYPICAL) = 36400 / RISET (Amps)
Do not use RISET values below 26kΩ because the maxi-
mum current rating of the device may be exceeded.
RISET values larger than 60kΩ are not recommended
and do not provide a lower limit current than 500mA. If
the output drops below 1V (typ), the MAX8586 shifts to a
short-circuit current-limit threshold that is 30% above the
programmed level given by the ILIM(TYPICAL) formula.
Input Power Supply and Capacitance
To limit the input voltage drop during momentary output
load transients, connect a capacitor from IN to ground.
A 1µF ceramic capacitor is required for local decou-
pling; however, higher capacitor values further reduce
the voltage drop at the input. When driving inductive
loads, a larger capacitance may be needed to prevent
voltage spikes from exceeding the MAX8586’s absolute
maximum ratings.
Output Capacitance
A capacitor as large as 500µF is allowed on the output
to smooth out transients and/or increase rise/fall times.
Larger output capacitance may be used, but the result-
ing output charge time during startup may exceed the
fault-blanking period resulting in a FAULT flag.
Driving Inductive Loads
A wide variety of devices (mice, keyboards, cameras,
and printers) typically connect to the USB port with
cables, adding an inductive component to the load. This
inductance causes the output voltage at the USB port to
oscillate during a load step. The MAX8586 drives induc-
tive loads; however, care must be taken to avoid
exceeding the device’s absolute maximum ratings.
Usually, the load inductance is relatively small, and the
MAX8586’s input includes a substantial bulk capaci-
tance from an upstream regulator as well as local
bypass capacitors, limiting overshoot. If severe ringing
occurs because of large load inductance, clamp the
MAX8586 output below +6V and above -0.3V.
Turn-On and Turn-Off Behavior
The MAX8586 features a slow turn-on and turn-off, mini-
mizing loading transients on the upstream power
source. SEL sets the active polarity of the logic inputs of
the MAX8586. Drive ON to the same logic state as SEL
to enable the output. Drive ON to the opposite logic
state as SEL to disable the output (see Table 1). The
output enters a high-impedance state when disabled.
Table 1. SEL/ON Inputs
SEL
High
High
Low
Low
ON
High
Low
High
Low
OUT STATE
Enabled
Disabled
Disabled
Enabled
Layout and Thermal Dissipation
Keep all input/output traces as short as possible to
reduce the effect of undesirable parasitic inductance
and optimize the switch response time to output short-
circuit conditions. Place input and output capacitors no
more than 5mm from device leads. Connect IN and OUT
to the power bus with short traces. Wide power bus
planes at IN and OUT provide superior heat dissipation
as well. An active switch dissipates little power with mini-
mal change in package temperature. Calculate the
power dissipation for this condition as follows:
P = IOUT2 x RON
At the normal operating current (IOUT = 0.5A) and the
maximum on-resistance of the switch (95mΩ), the
power dissipation is:
P = (0.5A)2 x 0.95mΩ = 24mW
The worst-case power dissipation occurs when the out-
put current is just below the current-limit threshold with
an output voltage greater than 1V. In this case, the
power dissipated in the switch is the voltage drop
across the switch multiplied by the current limit:
P = ILIM x (VIN - VOUT)
For a 5.5V input and 1V output, the maximum power
dissipation is:
P = 1.6A x (5.5V - 1V) = 7.2W
_______________________________________________________________________________________ 9
Share Link: 