MAX1558 Datasheet, PDF(10/12 Page) Maxim Integrated Products – Dual, 3mm x 3mm, 1.2A/Programmable-Current USB Switches with Autoreset

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MAX1558 Datasheet, PDF (10/12 Pages) Maxim Integrated Products – Dual, 3mm x 3mm, 1.2A/Programmable-Current USB Switches with Autoreset

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Dual, 3mm x 3mm, 1.2A/Programmable-Current

USB Switches with Autoreset

Applications Information

Setting the Current Limit

A resistor from ISET to ground programs the current-

limit value for both outputs. Use a resistor between

26kâ¦ and 86kâ¦ to set the current limit according to

the formula:

ILIM(TYPICAL) = 36400 / RISET (Amps)

Do not use RISET values below 26kâ¦ because the maxi-

mum current rating of the device may be exceeded.

RISET values larger than 60kâ¦ are not recommended

and do not provide a lower limit current than 500mA.

If the output drops below 1V (typ), the MAX1558 shifts

to a short-circuit current-limit threshold that is 30%

above the programmed level given by the ILIM(TYPICAL)

formula. If the short-circuit threshold is exceeded, the

switch shuts off immediately (no 20ms delay) and

ramps the current back up in approximately 3ms. If the

short persists and the current ramps all the way up to

the short-circuit limit again, the switch again turns off. If

the short still persists, the output pulses this way for

20ms, at which time the switch turns off and autoreset

mode begins.

Input Capacitor

INA and INB provide the power for all control and

charge-pump circuitry and must be connected together

externally. Connect a capacitor from IN_ to ground to

limit the input-voltage drop during momentary output

short-circuit conditions. A 0.1ÂµF ceramic capacitor is

required for local decoupling; higher capacitor values

further reduce the voltage drop at the input. When dri-

ving inductive loads, a larger capacitance prevents

voltage spikes from exceeding the MAX1558/

MAX1558Hsâ absolute maximum ratings.

Output Capacitor

Place a 1ÂµF or greater capacitor at each output for

noise immunity. When starting up into very large capac-

itive loads, the switch may pulse the output current at

the short-circuit current-limit program level until the out-

put voltage rises above 1V. Then, the capacitor contin-

ues to charge at the full, continuous current-limit

program level. There is no limit to the output capacitor

size, but to prevent a startup fault assertion, the capaci-

tor must charge up within the fault-blanking delay peri-

od. Typically, starting up into a 500ÂµF or smaller

capacitor does not trigger a fault output. In addition to

bulk capacitance, small-value (0.1ÂµF or greater) ceram-

ic capacitors improve the outputâs resilience to electro-

static discharge (ESD).

Driving Inductive Loads

A wide variety of devices (mice, keyboards, cameras,

and printers) can load the USB port. These devices com-

monly connect to the port with cables, which can add an

inductive component to the load. This inductance caus-

es the output voltage at the USB port to ring during a

load step. The MAX1558/MAX1558H are capable of dri-

ving inductive loads, but avoid exceeding the devicesâ

absolute maximum ratings. Usually the load inductance

is relatively small, and the MAX1558/MAX1558Hsâ

input includes a substantial bulk capacitance from an

upstream regulator as well as local bypass capacitors,

limiting overshoot. If severe ringing occurs due to large

load inductance, clamp the MAX1558/MAX1558Hsâ out-

put below +6V and above -0.3V.

Turn-On and Turn-Off Behavior

In the absence of faults, the MAX1558/MAX1558Hsâ

internal switches turn on and off slowly under the control

of the ON_ inputs. Transition times for both edges are

approximately 4ms. The slow charge-pump switch drive

minimizes load transients on the upstream power source.

Under thermal fault and UVLO, the power device turns

off rapidly (100ns) to protect the power device.

Layout and Thermal Dissipation

To optimize the switch response time to output short-

circuit conditions, keep all traces as short as possible

to reduce the effect of undesirable parasitic induc-

tance. Place input and output capacitors no more than

5mm from device leads. All IN_ and OUT_ pins must be

connected with short traces to the power bus. Wide

power-bus planes provide superior heat dissipation

through the switch IN_ and OUT_ pins. While the

switches are on, power dissipation is small and the

package temperature change is minimal. Calculate the

power dissipation for this condition as follows:

P = (IOUT_)2 RON

For the maximum operating current (IOUT_ = 1.2A) and

the maximum on-resistance of the switch (125mâ¦), the

power dissipation is:

P = (1.2A)2 x 0.125â¦ = 180mW per switch

The worst-case power dissipation occurs when the

switch is in current limit and the output is greater than

1V. The instantaneous power dissipated in each switch

is the voltage drop across the switch multiplied by the

current limit. The fault-blanking circuit turns the output

off if the fault persists for 20ms, while the autoreset cir-

cuit can turn it back on after 20ms in the off state. Thus,

the average worst-case power is approximately 50% of

the instantaneous value.

P = 0.5 x (ILIM) x (VIN_ - VOUT_)

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