MIC2590B_08 Datasheet, PDF(22/23 Page) Micrel Semiconductor

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MIC2590B_08 Datasheet, PDF (22/23 Pages) Micrel Semiconductor – Dual-Slot PCI Hot Plug Controller

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Micrel, Inc.

Power Supply Decoupling

In general, prudent system design requires that power

supplies used for logic functions should have less than

100mV of noise at frequencies of 100kHz and above. This

is especially true given the speeds of moden logic

families, such as the 1.2micron CMOS used in the

MIC2590B. In particular, the â12V supply should have

less than 100mV of peak-to-peak noise at frequencies of

1MHz or higher. This is because the â12V supply is the

most negative potential applied to the IC, and is therefore

connected to the device's substrate. All of the subcircuits

integrated onto the silicon chip are hence subjected by

capacities coupling to any HF noise on the â12V supply.

While individual capacitances are quite low, the amount of

injected energy required to cause a "glitch" can also be

quite low at the internal nodes of high speed logic circuits.

Less obviously, but equally important, is the fact that the

internal charge pump for the 3.3VAUX supplies is

somewhat susceptible to noise on the +12V input when

that input is at or near zero volts. The +12V supply should

not carry HF noise in excess of 200mV peak-to-peak with

respect to chip ground when it is in the "off" state.

If either the â12V input, the +12V input, of both supplies

do carry significant HF noise (as can happen when they

are locally derived by a switching converter), the solution

is both small and inexpensive. An LC filter made of a

ferrite bead between the noisy power supply input and the

MIC2590B, followed by a "composite capacitor" from the

affected MIC2590B input pin to ground will suffice for

almost any situation. A good composite capacitor for this

purpose is the parallel combination of a 47ÂµF tantalum

bulk decoupling capacitor, and one each 1ÂµF and 0.01ÂµF

ceramic capacitors for high-frequency bypass. A

suggested ferrite bead for such use is Fair-Rite Products

Corporation part number 2743019447 (this is a surface-

mountable part). Similar parts from other vendors will also

work well, or a 0.27ÂµH, air-core coil can be used.

Noisy VIN

To MIC2590B

SMT Ferrite Bead

Fair-Rite Products

Type 2743019447

47ÂµF

1ÂµF

10nF

Tantalum Ceramic Ceramic

Figure 11. Filter Circuit for Noisy Supplies

(+3.3V and/or â12V)

It is theoretically possible that high-amplitude, HF noise

reflected back into one or both of the MIC2590Bâs â12V

outputs could interfere with proper device operation,

although such noisy loads are unlikely to occur in the real

world. If this becomes an application-specific concern, a

pair of filters similar to that in Figure 11 will provide the

required HF bypassing. The capacitors would be

connected to the MIC2590Bâs â12V output pins, and the

ferrite beads would be placed between the â12V output

pins and the loads.

September 2008

MIC2590B

â12V Input Clamp Diode

The â12V input to the MIC2590B is the most negative

potential on the part, and is therefore connected to the

chipâs substrate (as described in âPower Supply

Decoupling,â above). Although no particular sequencing of

the â12V supply relative to the other MIC2590B supplies

is required for normal operation, this substrate connection

does mean that the â12V input must never exceed the

voltage on the GROUND pin of the IC by more than 0.3

volts. In some systems, even though the â12V supply will

discharge towards ground potential when it is turned OFF,

the possibility exists that power supply output ringing or

L(di/dt) effects in the wiring and on the PCB itself will

cause brief transient voltages in excess of +0.3V to

appear at the â12V input. The simplest way to deal with

such a transient is to clamp it with a Schottky diode. The

diodeâs a node should be physically placed directly at the

â12V input to the MIC2590B, and its cathode should have

as short a path as possible back to the partâs ground. A

good SMT part for this application is ON Semiconductorâs

type MBRS140T3 (1A, 40V). Although the 40V rating of

this part is a bit gratuitous, it is an inexpensive industry-

standard part with many second sources. Unless it is

absolutely known in advance that the voltage on the ââ

12Vâ inputs will never exceed 0.0V at the ICâs â12V input

pins, itâs wise to at least leave a position for this diode in

the board layout and then remove it later. This final

determination should be made by observations of the

voltage at the â12V input with a fast storage oscilloscope,

under turn-on and turn-off conditions.

Gate Resistor Guidelines

The MIC2590B controls four external power MOSFETs,

which handle the high currents for each of the two 3.3V

and 5V outputs. A capacitor (CGATE) is connected in the

application circuit from each GATE pin of the MIC2590B

to ground. Each CGATE controls the ramp-up rate of its

respective power output (e.g., 5VOUTB). These capacitors,

which are typically in the 10nF range, cause the GATE

outputs of the MIC2590B to have very low AC

impedances to ground at any significant frequency. It is

therefore necessary to place a modest value of gate

damping resistance (RGATE) between each CGATE and the

gate of its associated MOSFET. These resistances

prevent high-frequency MOSFET source-follower oscilla-

tions from occurring. The exact value of the resistors used

is not critical; 47â¦ is usually a good choice. Each RGATE

should be physically located directly adjacent to the

MOSFET gate lead to which it connects.

MIC2590B

GATE

RGATE

External

MOSFET

CGATE

Figure 12. Proper Connection of CGATE and RGATE

M9999-091808

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