MIC2587R-2YM - Micrel - Datasheet.Directory

MIC2587/MIC2587R

Single-Channel, Positive High-Voltage

Hot Swap Controller

Power, Connect, and Protect is a trademark of Micrel Inc.

Micrel, Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax +1 (408) 474-1000 • http://www.micrel.com

October 2004

M9999-102204

(408) 955-1690

General Description

The MIC2587 and MIC2587R are single-channel positive

voltage hot swap controllers designed to provide safe

insertion and removal of boards for systems that require

live (always-powered) backplanes. These devices use few

external components and act as controllers for external N-

channel power MOSFET devices to provide inrush current

control and output voltage slew rate control. Overcurrent

fault protection is provided via programmable analog

foldback current limit circuitry equipped with a

programmable overcurrent filter. These protection circuits

combine to limit the power dissipation of the external

MOSFET to insure that the MOSFET is in its SOA during

fault conditions. The MIC2587 provides a circuit breaker

function that latches the output MOSFET off if the load

current exceeds the current limit threshold for the duration

of the programmable timer. The MIC2587R provides a

circuit breaker function that automatically attempts to

restart power after a load current fault at a low duty cycle to

prevent the MOSFET from overheating. Each device

provides either an active-HIGH (-1BM) or an active-LOW

(-2BM) “Power-is-Good” signal to indicate that the output

load voltage is within tolerance.

Data sheets and support documentation can be found on

Micrel’s web site at www.micrel.com.

Features

• MIC2587: Pin-for-pin functional equivalent to the LT1641

• Operates from +10V to +80V with 100V ABS MAX operation

• Industrial temperature spec ifications at V

= +24V and

= +48V

• Programmable current limit with analog foldback

• Active current regulation minimizes inrush current

• Electronic circuit breaker for overcurrent fault protection

- Output latch off (MIC2587) or

- Output auto-retry (MIC2587R)

• Fast responding circuit breaker (< 2µs) to short circuit loads

• Programmable input undervoltage lockout

• Fault Reporting:

Open-drain “Power-is-Good” output for enabling DC/DC

converter(s)

- Active-HIGH: MIC2587-1/MIC2587R-1

- Active-LOW: MIC2587-2/MIC2587R-2

Applications

• General-purpose hot board insertion

• High-voltage, high-side electronic circuit breaker

• +12V/+24V/+48V Distributed Power Systems

• +24V/+48V Industrial/Alarm Systems

• Telecom Systems

• Medical Systems

Ordering Information

Part Number

Standard Pb-Free

PWRGD Polarity Circuit Breaker Function Package

MIC2587-1BM MIC2587-1YM Active-HIGH Latched 8 pin SOIC

MIC2587-2BM MIC2587-2YM Active-LOW Latched 8 pin SOIC

MIC2587R-1BM MIC2587R-1YM Active- HIGH Auto-retry 8 pin SOIC

MIC2587R-2BM MIC2587R-2YM Active-LOW Auto-retry 8 pin SOIC

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Typical Application

MIC2587/87R Typical Application Circuit

Pin Configur ation

8-pin SOIC (M)

MIC2587-1BM

MIC2587R-1BM

8-pin SOIC (M)

MIC2587-2BM

MIC2587R-2BM

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Pin Description

Pin Number Pin Name Pin Function

1 ON

Enable Input: When the voltage at the ON pi n is hig her than the V

ONH

threshold, a start cycle

is initiated. An internal current source (I

GATEON

) is activated which charges the GAT E pin,

ramping up the voltage at this pin to turn on a n external MOSFET. Whenever the voltag e at

the ON pin is lower than the V

ONL

threshold, an undervoltage lockout condition is detected

and the I

GATEON

current source is disabled while the GATE pin is pulled low by another

internal current source (I

GATEOFF

). After a load current fault, toggling the ON pin LOW will

reset the circuit breaker then back HIGH (ON pin) will initiate another start cycl e.

2 FB

Output Voltage Feedback Input: This pin is connected to an external resistor divider that is

used to sample the output load voltage. The voltage at this pin is measured against an

internal comparator whose output controls the PWRGD (or /PWRGD) signal. PWRG D (or

/PWRGD) asserts when the FB pin voltage crosses the V

FBH

threshold. When the FB pin

voltage is lower than its V

FBL

threshold, PWRGD (or /PWRGD) is de-asserted. The FB

comparator exhibits a typical hysteresis of 80mV.

The FB pin voltage also affect s the MIC2587/MIC2587R’s foldback current limit operation

(see the “Functional Descripti on” sectio n for further information).

PWRGD

(MIC2587-1)

(MIC2587R-1)

Active-HIGH

/PWRGD

(MIC2587-2)

(MIC2587R-2)

Active-LOW

Power-is-Good (PWRGD or /PWRGD), Open-drain Output: This pin remains de-asserted

during start up while the FB pin voltage is bel ow the V

FBH

threshold. Once the voltage at the

FB pin rises above the V

FBH

threshold, the Power-is-Good output asserts with minimal delay

(typically ≤ 5µs).

For the (-1) options, the PWRGD output pin will be high-impedance when the F B pin voltage

is higher than V

FBH

and will pull down to GND when the FB pin volta ge is less than V

FBL

For the (-2) options, the /PWRGD output pin will be high-im pedance when the FB pin

voltage is lower than V

FBL

and will pull down to GND when the FB pin voltage is higher than

FBH

The Power-is-Good output pin is connect ed to an open-drain, N-channel transistor

implemented with high-voltage structures. T hese transistors are capable of operating with

pull-up resistors to supply voltages as high as 100V.

To use this signal as a logic control i n low-voltage dc-dc conversion applications, an external

pull-up resistor bet ween this p in and the logic supply voltage is recommended, unless an

internal pull-up impedance is provided by the dc-dc module or other devi c e (load).

4 GND Tie this pin directly to the system’s analog GND pla ne

5 TIMER

Current Limit Response Timer: A capacitor connected from this pin to GND provides

overcurrent filtering to prevent nuisance “tripping” of the circuit breaker by setting the time

FLT

) for which the controller is allo wed to remain in current limit. O nce the MIC2587 circuit

breaker trips, the output latches off. Under normal (steady state) operation, the TIMER pin

is held to GND by an internal 3.5µA current source (I

TIMERDN

). When the voltage acr oss the

external sense resistor exceeds the V

TRIP

threshold, an internal 65µA current source

TIMERUP

) is activated to charge the capacitor connecte d to the TIMER pin. When the TIMER

pin voltage reac hes the V

TIMERH

threshold, the circuit break er is tripped pullin g the GATE pin

low, the I

TIMERUP

current source is disabled, and the TIMER pin capacitor is discharged by

the I

TIMERDN

current source. When the voltage at the TIMER pin is less than 0.5V, the

MIC2587 can be restarted by toggling the ON pin LO W then HIGH.

For the MIC2587R, the capacitor connected to the TIMER pin sets the period of auto-retry

where the duty cycle is fixed a t a nominal 5%.

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Pin Description

Pin Number Pin Name Pin Function

6 GATE

Gate Drive Output: This pin is the output of an internal charge pump co nnected to the gate

of an external, N-channel power MOSFET. The charge pump has bee n designed to provide

a minimum gate drive (∆V

GATE

= V

GATE

- V

) of +7.5V over the input supply’s full operating

range. When the ON pin voltage is higher than the V

ONH

threshold, a 16µA current source

GATEON

) charges the GATE pin.

When in current limit, the output voltage at the GATE pin is adjusted so that the voltage

across the external sense resistor is held equal to V

TRIP

while the capacitor connected to the

TIMER pin charges. If the current limit condition goes away before the TIMER pin voltage

rises above the V

TIMERH

threshold, then steady-state operation resumes.

The GATE output pi n is shut down whenever: (1) the input supply voltage is lower than the

UVL

threshold, (2) the ON pin voltage is lower than the V

ONL

threshold, (3) the TIMER pin

voltage is higher than the V

TIMERH

threshold, or (4) the difference between the VCC and

SENSE pins is greater than V

TRIP

while the TIMER pin is grounded. For cases (3) an d (4) –

overcurrent fault conditions – the G ATE is immediatel y pulled to ground by I

GATEFLT

, a 30mA

(minimum) pull-down current.

7 SENSE

Circuit Breaker Sense Input: This pin is the (-) Kelvin sense connection for the output

supply rail. A lo w-valued resistor (R

SENSE

) between this pin and t he VCC pin sets the cir cuit

breaker’s current limit trip point. When the current limit detector circuit is enabled (as well as

the current limit timer), while the FB pin voltage remains higher than 1V, the voltag e across

the sense resistor (V

-V

SENSE

) will be regulated to V

TRIP

(47mV, typically) to maintain a

constant current into the load. When the FB pin voltage is less than ≅0.5V, the voltage

across the sense resistor decreases linearly to a minimum of 12mV (typical) when the FB

pin voltage is at 0V.

To disable the circuit breaker (and defeat all current limit protections), the SENSE pin and

the VCC pin can be tied together.

8 VCC

Positive Supply Voltage Input: This pin is the (+) Kelvin sense connection for the output

supply rail. The nominal operating voltage range for the MIC2587 and the MIC2587R is

+10V to +80V, and VCC can withstand input transients up to +100V. An undervoltage

lockout circuit holds the GAT E pin low whenever the supply voltage to the MIC2587 and the

MIC2587R is less than the V

UVH

threshold.

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Absolute Maximum Ratings

(1)

(All voltages are referred to GND)

Supply Voltage (V

) pin..............................-0.3V to +100V

GATE pin......................................................-0.3V to +100V

ON, SENSE pins..........................................-0.3V to +100V

PWRGD, /PWRGD pins...............................-0.3V to +100V

FB pin...........................................................-0.3V to +100V

TIMER pin ........................................................-0.3V to +6V

ESD Rating

Human Body Model.................................................2kV

Machine Model ......................................................200V

Lead Temperature (Soldering)

Standard Package (-xBM)

IR Reflow…………………………240°C + 0°C/-5°C

Lead-Free Package (-xYM)

IR Reflow…………………………260°C + 0°C/-5°C

Operating Ratings

(2)

Supply Voltage (V

)...................................... +10V to +80V

Ambient Temperature Range (T

)...............-40°C to +85°C

Junction Temperature (T

)....................................... +125°C

Package Thermal Resistance (θ

)

8-pin SOIC......................................................160 °C/W

DC Electrical Characteristics

(4)

= +24V and +48V, T

= 25°C, unless otherwise noted. BOLD indicates specifications apply ov er the full operating temperature

range of -40°C to +85°C.

Symbol Parameter Condition Min Typ Max Units

Supply Voltage 10 80 V

Supply Current 2 5 mA

UVH

UVL

Supply Voltage Undervoltage Lockout V

rising

falling 7.5

7.0 8.0

7.5 8.5

8.0 V

HYSLO

VCC Undervoltage Lockout Hysteresis 500 mV

FBH

Feedback Pin Voltage Hig h T hreshold FB Low-to-High transition 1.280 1.313 1.345 V

FBL

Feedback Pin Voltage Low Threshold FB High-to-Low transition 1.208 1.233 1.258 V

HYSFB

Feedback Voltage H yster esis 80 mV

∆V

FB Pin Threshold Line R egulation 10V ≤ V

≤ 80V -0.05 0.05 mV/V

FB Pin Input Current 0V ≤ V

≤ 3V -1 1 µA

TRIP

Circuit Breaker Trip Voltage, V

-V

SENSE

= 0V (See Fig. 1)

= 1V (See Fig. 1) 5

39 12

47 17

55 mV

∆V

GATE

MOSFET Gate Drive, V

GATE

-V

+10V ≤ V

≤ +80V 7.5 18 V

GATEON

GATE Pin Pull-up Current Start cycle, V

GATE

= 7V -10 -16 -22 µA

GATEFLT

GATE Pin rapid pull-down current (during

a fault condition, until V

GATE

= V

GATE[TH]

)

GATE[TH]

is the MOSFET threshold)

- V

SENSE

) = (V

TRIP

+ 10mV)

GATE

= 5V 30

200

GATEOFF

GATE Pin Turn-off Current Normal turn-off, or from V

GATE[TH]

(MOSFET) to 0V after a fault condition 1.8 mA

TIMERUP

TIMER Pin Charging Current

– V

SENSE

) > V

TRIP

TIMER

= 0V -24 -65 -120 µA

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DC Electrical Characteristics

(4)

= +24V and +48V, T

= 25°C, unless otherwise noted. BOLD indicates specifications apply ov er the full operating temperature

range of -40°C to +85°C.

Symbol Parameter Condition Min Typ Max Units

TIMERDN

TIMER Pin Pull-down Current (V

– V

SENSE

) < V

TRIP

TIMER

= 0.6V 1.5 3.5 5 µA

TIMERH

TIMER Pin High Threshold Voltage 1.280 1.313 1.345 V

TIMERL

TIMER Pin Low Threshold Voltage 0.4 0.49 0.6 V

ONH

ON Pin High Threshold Volta ge ON Low-to-High transition 1.280 1.313 1.355 V

ONL

ON Pin Low Threshold Voltage ON High-to-Low transition 1.208 1.233 1.258 V

HYSON

ON Pin Hysteresis 80 mV

ON Pin Input Current 0V ≤ V

≤ 80V 2 µA

Power-Good Output Voltage PWRGD or /PWRGD = LOW

= 1.6 mA

= 4 mA

0.4

0.8

OFF

Power-Good Leakage Curren t PWRGD or /PWRGD = Open-Drain

= V

, V

= 1.5V 10 µA

AC Electrical Characteristics

= +24V and +48V, T

= 25°C unless otherwise noted. BOLD indicates specifications apply over the full operating temperature

range of -40°C to +85°C.

Symbol Parameter Condition Min Typ Max Units

PONLH

ON High to GATE High IRF530, C

GATE

= 10nF 3 ms

PONHL

ON Low to GATE Low V

= 48V, IRF530, C

GATE

= 10nF 1 ms

PFBLH

FB Valid to PWRGD High

(MIC2587/87R-1) R

= 50kΩ pull-up to 48V

=100pF 2 µs

PFBHL

FB Invalid to PWRGD Low

(MIC2587/87R-1) R

= 50kΩ pull-up to 48V

=100pF 4 µs

PFBHL

FB Valid to /PWRGD Low

(MIC2587/87R-2) R

= 50kΩ pull-up to 48V

=100pF 4 µs

PFBLH

FB Invalid to /PWRGD High

(MIC2587/87R-2) R

= 50kΩ pull-up to 48V

=100pF 2 µs

OCSENSE

Overcurrent Sense to GATE Lo w

Trip Time (V

- V

SENSE

) = (V

TRIP

+ 10mV)

Figure 7 1 2 µs

Notes:

1. Exceeding the absolute maximum rating may damage the device.

2. The device is not guaranteed to function outside its operating rating.

3. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5k in series with 100pF.

4. Specification for packaged product only.

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Timing Diagrams

Figure 1. Foldback Cu rrent Limit Transfer Characteristic

Figure 2. ON to GATE Timing

Figure 3. MIC2587/87R-1 F B to PWRGD Timing

Figure 4. MIC2587/87R-2 F B to /PWRGD Timing

Figure 5. Overcurrent Sense to GATE Timing

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Function Diagram

MIC2587/MIC2587R Block Diagram

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Functional Description

Hot Swap Insertion

When circuit boards are inserted into systems carrying live

supply voltages ("hot swapped"), high inrush currents often

result due to the charging of bulk capacitance that resides

across the circuit board's supply pins. These current spikes

can cause the system's supply voltages to temporarily go

out of regulation causing data loss or system lock-up. In

more extreme cases, the transients occurring during a hot

swap event may cause permanent damage to connectors

or on-board components.

The MIC2587/MIC2587R is designed to address these

issues by limiting the maximum current that is allowed to

flow during hot swap events. This is achieved by

implementing a constant-current control loop at turn-on. In

addition to inrush current control, the MIC2587 and

MIC2587R incorporate input voltage supervisory functions

and user-programmable overcurrent protection, thereby

providing robust protection for both the system and the

circuit board.

Input Supply Transient Suppression and Filtering

The MIC2587/MIC2587R is guaranteed to withstand

transient voltage spikes up to 100V. However, voltage

spikes in excess of 100V may cause damage to the

controller. In order to suppress transients caused by

parasitic inductances, wide (and short) power traces

should be utilized. Alternatively, a heavier trace plating will

help minimize inductive spikes that may arise during

events (e.g., short circuit loads) that can cause a large di/dt

to occur. External surge protection, such as a clamping

diode, is also recommended as an added safeguard for

device (and system) protection. Lastly, a 0.1µF decoupling

capacitor from the VCC pin to ground is recommended to

assist in noise rejection. Place this filter capacitor as close

as possible to the VCC pin of the controller.

Start-Up Cycle

When the power supply voltage to the MIC2587/MIC2587R

is higher than the V

UVH

and the V

ONH

threshold voltages, a

start cycle is initiated. When the controller is enabled, an

internal 16µA current source (I

GATEON

) is turned on and the

GATE pin voltage rises from 0V with respect to ground at a

rate equal to:

GATE

dt =I

GATEON

GATE

(1)

The internal charge pump has sufficient output drive to fully

enhance commonly available power MOSFETs for the

lowest possible DC losses. The gate drive is guaranteed

to be between 7.5V and 18V over the entire supply voltage

operating range (10V to 80V), so 60V BV

DSS

and 30V

DSS

N-channel power MOSFETs can be used for +48V

and +24V applications, respectively. However, an external

Zener diode (18-V) connected from the source to the gate

as shown in the "Typical Applications" circuit is highly

recommended. A good choice for an 18-V Zener diode in

this application is the MMSZ5248B, available in a small

SOD123 package.

GATE

is used to adjust the GATE voltage slew rate while

R3 minimizes the potential for high-frequency parasitic

oscillations from occurring in M1. However, note that

resistance in this part of the circuit has a slight destabilizing

effect upon the MIC2587/MIC2587R's current regulation

loop. Compensation resistor R4 is necessary for

stabilization of the current regulation loop. The current

through the power transistor during initial inrush is given

by:

INRUSH

LOAD

×I

GATEON

GATE

(2)

The drain current of the MOSFET is monitored via an

external current sense resistor to ensure that it never

exceeds the programmed threshold, as described in the

"Circuit Breaker Operation" section.

A capacitor connected to the controller’s TIMER pin sets

the value of overcurrent detector delay, t

FLT

, which is the

time for which an overcurrent event must last to signal a

fault condition and to cause an output latch-off. These

devices will be driving a capacitive load in most

applications, so a properly chosen value of C

TIMER

prevents

false-, or nuisance-, tripping at turn-on as well as providing

immunity to noise spikes after the start-up cycle is

complete. The procedure for selecting a value for C

TIMER

given in the "Circuit Breaker Operation" section.

Overcurrent Protection

The MIC2587 and the MIC2587R use an external, low-

value resistor in series with the drain of the external

MOSFET to measure the current flowing into the load. The

VCC connection (Pin 8) and the SENSE connection (Pin 7)

are the (+) and (-) inputs, respectively, of the device's

internal current sensing circuits. Kelvin sense connections

are strongly recommended for sensing the voltage across

these pins. See the “Applications Information” for further

details.

The nominal current limit is determined by the following

equation.

SENSE

TRIP(TYP)

LIMIT

I= (3)

where V

TRIP(TYP)

is the typical current limit threshold

specified in the datasheet and R

SENSE

is the value of the

selected sense resistor. As the MIC2587 and the

MIC2587R employ a constant-current regulation scheme in

current limit, the charge pump’s output voltage at the

GATE pin is adjusted so that the voltage across the

external sense resistor is held equal to V

TRIP

while the

capacitor connected to the TIMER pin is being charged. If

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the current-limit condition goes away before the TIMER pin

voltage rises above the V

TIMERH

threshold, then steady-

state operation resumes. To prevent excessive power

dissipation in the external MOSFET under load current

fault conditions, the FB pin voltage is used as the control

element in a circuit that lowers the current limit as a

function of the output voltage. When the load current

increases to the point where the output voltage at the load

approaches 0V (likewise, the MIC2587/MIC2587R’s FB pin

voltage also approaches 0V), the result is a proportionate

decrease in the maximum current allowed into the load.

This foldback current limit subcircuit’s transfer

characteristic is shown in Figure 1. Under excessive load

conditions (output and FB voltage equals 0V), the foldback

current limiting circuit controls the MIC2587/MIC2587R’s

GATE drive to force a constant 12mV (typical) voltage drop

across the external sense resistor.

Circuit Breaker Operation

The MIC2587/MIC2587R employ an electronic circuit

breaker that protects the external N-channel power

MOSFET and other system components against large-

scale output current faults, both during initial card insertion

or during steady-state operation. The current limit threshold

is set via an external resistor, R

SENSE

, connected between

the circuit’s V

pin and SENSE pin. For the

MIC2587/MIC2587R, a fault current timing circuit is set via

an external capacitor (C

TIMER

) that determines the length of

the time delay (t

FLT

) for which the controller remains in

current limit before the circuit breaker is tripped.

Programming the response time of the overcurrent detector

helps to prevent nuisance tripping of the circuit breaker

because of high inrush currents charging bulk and

distributed capacitive loads. The nominal overcurrent

response time is calculate d using the following equation:

TIMERUP

TIMERHFILTER

FLT

IVC

t×

F)(C20(ms)t

FILTERFLT

×=

(4)

Whenever the voltage across R

SENSE

exceeds the

MIC2587/MIC2587R’s nominal circuit breaker threshold

voltage of 47mV during steady-state operation, two things

occur:

1. A constant-current regulation loop will engage

within 1µs after an overcurrent condition is

detected by R

SENSE

, and the control loop is

designed to hold the voltage across R

SENSE

equal

to 47mV. This feature protects both the load and

the MIC2587/MIC2587R circuits from excessively

high currents.

2. Capacitor C

TIMER

is then charged up to the V

TIMERH

threshold (1.313V) by an internal 65µA current

source (I

TIMERUP

). If the excessive current persists

such that the voltage across C

TIMER

crosses the

TIMERH

threshold, the circuit breaker trips and the

GATE pin is immediately pulled low by a 30mA

(minimum) internal current sink. This operation

turns off the MOSFET quickly and disconnects the

input from the load. The value of C

TIMER

should be

selected to allow the circuit's minimum regulated

output current (I

OUT

) to equal I

LIMIT

for somewhat

longer than the time it takes to charge the total

load capacitance.

An initial value for C

TIMER

is found by calculating the time it

will take for the MIC2587/MIC2587R to completely charge

up the output capacitive load. Assuming the load is

enabled by the PWRGD (or /PWRGD) signal of the IC, the

turn-on delay time is derived from the following expression,

I = C × (dV/dt):

TURN-ON

LOAD

CC(MAX)

LIMIT (5)

Using parametric values for the MIC2587/MIC2587R, an

expression relating a worse-case design value for C

TIMER

using the MIC2587/MIC2587R specification limits, to the

circuit's turn-on delay time is:

)TIMERH(MIN

X)TIMERUP(MAON-TURN

TIMER(MAX)

VIt

C×

⎟

⎠

⎞

⎜

⎝

⎛

×= 1.280V

A120

ON-TURNTIMER(MAX)

⎟

⎠

⎞

⎜

⎝

⎛××= sec

1094tC

ON-TURN(MAX)TIMER

(6)

For example, in a system with a C

LOAD

= 1000µF, a

maximum V

= +72V, and a maximum load current on a

nominal +48V buss of 1.65A, the nominal circuit design

equations steps are:

1. Choose I

LIMIT

= I

HOT_SWAP(nom)

= 2A (1.65A + 20%);

2. Select an R

SENSE

(Closest 1% standard value is

19.6mΩ);

3. Using I

CHARGE

= I

LIMIT

= 2A, the application circuit

turn-on time is calculated using Equation 5:

TURN-ON

=1000

F×72V

(

)

2A =36ms

Allowing for capacitor tolerances and a nominal 36ms turn-

on time, an initial worse-case value for C

TIMER

is:

F3.38

sec

10940.036sC

TIMER(MAX)

⎟

⎠

⎞

⎜

⎝

⎛××=

The closest standard ±5% tolerance capacitor value is

3.3µF and would be a good initial starting value for

prototyping.

Whenever the MIC2587 is not in current limit, C

TIMER

discharged to GND by an internal 3.5µA current sink

TIMERDN

For the MIC2587R, the circuit breaker automatically resets

after (20) t

FLT_AUTO

time constants. If the fault condition still

exists, capacitor C

TIMER

will begin to charge up to the

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)

TIMERH

threshold, and if exceeded, trip the circuit breaker.

Capacitor C

TIMER

will then be discharged by I

TIMERDN

until

the voltage across C

TIMER

drops below the V

TIMERL

threshold, at which time another start cycle is initiated. This

will continue until either of the following occurs: a) the fault

condition is removed, b) the input supply voltage power is

removed/recycled, or c) the ON pin is toggled LOW then

HIGH. The duty cycle of the auto-restart function is

therefore fixed at 5% and the period of the auto-restart

cycle is given by:

FLT_AUTORESTARtAUTO

t20t ×=

−

()(

TIMERUP

TIMERLTIMERHTIMER

RESTART-AUTO

IVVC

20t −×

×=

⎟

⎠

⎞

⎜

⎝

⎛

×= F

250Ct

TIMERRESTART-AUTO

(7)

The auto-restart period for the example above where the

worse-ca se C

TIMER

was calculated to be 3.3µF is:

AUTO-RESTART

= 825ms

Input Undervoltage Lock out

The MIC2587/MIC2587R have an internal undervoltage

lockout circuit that inhibits operation of the controller’s

internal circuitry unless the power supply voltage is stable

and within an acceptable tolerance. If the supply voltage to

the controller, with respect to ground is greater than the

UVH

threshold voltage (8V typical), then the controller’s

internal circuits are enabled and the controller is then ready

for normal operation pending the state of the ON pin

voltage. Once in steady-state operation, the controller’s

internal circuits remain active so long as the supply voltage

with respect to ground is higher than the controller’s

internal V

UVL

threshold voltage (7.5V typical).

Power-is-Good Output Signals

For the MIC2587-1 and MIC2587R-1, the power-good

output signal (PWRGD) will be high impedance when the

FB pin voltage is higher than the V

FBH

threshold and will

pull down to GND when the FB pin voltage is lower than

the V

FBL

threshold. For the MIC2587-2 and MIC2587R-2,

the power-good output signal (/PWRGD) will pull down to

GND when the FB pin voltage is higher than the V

FBH

threshold and will be high impedance when the FB pin

voltage is lower than the V

FBL

threshold. Hence, the (-1)

parts have an active-HIGH PWRGD signal and the (-2)

parts have an active-LOW /PWRGD output. PWRGD (or

/PWRGD) may be used as an enable signal for one or

more following DC/DC converter modules or for other

system uses as desired. When used as an enable signal,

the time necessary for the PWRGD (or /PWRGD) signal to

pull-up (when in high impedance state) will depend upon

the (RC) load at the Power-is-Good pin.

The Power-is-Good output pin is connected to an open-

drain, N-channel transistor implemented with high-voltage

structures. These transistors are capable of operating with

pull-up resistors to supply voltages as high as 100V.

Micrel MIC2587/MIC2587R

October 2004 12

M9999-102204

(408) 955-1690

Applications Information

External ON/OFF Control

The MIC2587/MIC2587R have an ON pin input that is used

to enable the controller to commence a start-up sequence

upon card insertion or to disable controller operation upon

card removal. In addition, the ON pin can be used to reset

the MIC2587/MIC2587R’s internal electronic circuit breaker

in the event of a load current fault. To reset the electronic

circuit breaker, the ON pin is toggled LOW then HIGH. The

ON pin is internally connected to an analog comparator

with 80mV of hysteresis. When the ON pin voltage falls

below its internal V

ONL

threshold, the GATE pin is

immediately pulled low. The GATE pin will be held low until

the ON pin voltage is above its internal V

ONH

threshold. The

external circuit's ON threshold voltage level is programmed

using a resistor divider (R1 & R2) as shown in the "Typical

Application” circuit. The equations to set the trip points are

shown below. For the following example, the external

circuit's ON threshold is set to V

ONH(EX)

= +37V, a value

commonly used in +48V Central Office power distribution

applications.

ONH(EX)

ONH

×R1+R2

⎛

⎝

⎜

⎞

⎠

⎟

(8)

Given V

ONH

and R2, a value for R1 can be determined. A

suggested value for R2 is that which will provide

approximately 100µA of current through the voltage divider

chain at V

= V

ONH

. This yields the following as a starting

point:

R2 =V

ONH(TYP)

100

=1.313V

100

=13.13kΩ

The closest standard 1% value for R2 is 13kΩ. Now,

solving for R1 yields:

R1=R2 ×V

ONH(EX)

ONH(TYP)

⎛

⎝

⎜

⎞

⎠

⎟

⎟ −1

⎡

⎣

⎢

⎤

⎦

⎥

⎥ =13kΩ× 37V

1.313V

⎛

⎝

⎜ ⎞

⎠

⎟ −1

⎡

⎣

⎢ ⎤

⎦

⎥ =353.3 kΩ

The closest standard 1% value for R1 is 357kΩ.

Using standard 1% resistor values, the external circuit's

nominal ON and OFF thresholds are:

ON(EX)

= +36V

OFF(EX)

= +34V

In solving for V

OFF(EX)

, replace V

ONH

with V

ONL

in Equation 8.

Output Voltage Po wer-is-Good Detection

The MIC2587/MIC2587R includes an analog comparator

used to monitor the output voltage of the controller through

an external resistor divider as shown in the “Typical

Application” circuit. The FB input pin is connected to the

non-inverting input and is compared against an internal

reference voltage. The analog comparator exhibits a

hysteresis of 80mV.

Setting the “Power-is-Good” threshold for the circuit follows

a similar approach as setting the circuit’s ON/OFF input

voltage. The equations to set the trip points are shown

below. For the following +48V telecom application, power-

is-good output signal PWRGD (or /PWRGD) is to be de-

asserted when the output supply voltage is lower than

+48V-10% (+43.2V).

OUT(NOT GOOD)

FBL

×R5 +R6

⎛

⎝

⎜

⎞

⎠

⎟

(9)

Given V

FBL

and R6, a value for R5 can be determined. A

suggested value for R6 is that which will provide

approximately 100µA of current through the voltage divider

chain at V

OUT(NOT GOOD)

= V

FBL

. This yields the following

equation as a starting point:

R6 =V

FBL(TYP)

100

=1.233V

100

=12.33 kΩ

The closest standard 1% value for R6 is 12.4kΩ. Now,

solving for R5 yields:

R5 =R6 ×V

OUT(NOT GOOD)

FBL(TYP)

⎛

⎝

⎜

⎞

⎠

⎟

⎟ −1

⎡

⎣

⎢

⎤

⎦

⎥

⎥ =12.4kΩ× 43.2V

1.233V

⎛

⎝

⎜ ⎞

⎠

⎟ −1

⎡

⎣

⎢ ⎤

⎦

⎥ =422 kΩ

The closest standard 1% value for R5 is 422kΩ.

Using standard 1% resistor values, the external circuit's

nominal “power-is-good” and “power-is-not-good” output

voltages are:

OUT(GOOD)

= +46V

OUT(NOT GOOD)

= +43.2V

In solving for V

OUT(GOOD)

, substitute V

FBH

for V

FBL

Equation 9.

Sense Resistor Selection

The sense resistor is nomi nally valued at:

RSENSE(NOM) =VTRIP(TYP)

IHOT_SWAP(NOM)

(10)

where V

TRIP(TYP)

is the typical (or nominal) circuit breaker

threshold voltage (47mV) and I

HOT_SWAP(NOM)

is the nominal

inrush load current level to trip the internal circuit breaker.

To accommodate worse-case tolerances in the sense

resistor (for a ±1% initial tolerance, allow ±3% tolerance for

variations over time and temperature) and circuit breaker

threshold voltages, a slightly more detailed calculation

must be used to determine the minimum and maximum hot

swap load curre nts.

As the MIC2587/MIC2587R's minimum current limit

threshold voltage is 39mV, the minimum hot swap load

current is determined where the sense resistor is 3% high:

HOT_SWAP(MIN)

=39mV

1.03×R

SENSE(NOM)

()

=37.9mV

SENSE(NOM)

Keep in mind that the minimum hot swap load current

should be greater than the application circuit's upper

steady-state load current boundary. Once the lower value

of R

SENSE

has been calculated, it is good practice to check

Micrel MIC2587/MIC2587R

October 2004 13

M9999-102204

(408) 955-1690

the maximum hot swap load current (I

HOT_SWAP(MAX)

) which

the circuit may let pass in the case of tolerance build-up in

the opposite direction. Here, the worse-case maximum is

found using a V

TRIP(MAX)

threshold of 55mV and a sense

resistor 3% low in value:

HOT_SWAP(MAX)

=55mV

0.97 ×R

SENSE(NOM)

()

=56.7mV

SENSE(NOM)

In this case, the application circuit must be sturdy enough

to operate over a ~1.5-to-1 range in hot swap load

currents. For example, if an MIC2587 circuit must pass a

minimum hot swap load current of 4A without nuisance

trips, R

SENSE

should be set to:

Ω== 9.75m

39mV

SENSE(NOM)

where the nearest 1% standard value is 9.76mΩ. At the

other tolerance extremes, I

HOT_SWAP(MAX)

for the circuit in

question is then simply:

HOT_SWAP(MAX)

=56.7mV

9.76mΩ=5.8A

With a knowledge of the application circuit's maximum hot

swap load current, the power dissipation rating of the

sense resistor can be determined using P = I

× R. Here,

The current is I

HOT_SWAP(MAX)

= 5.8A and the resistance

SENSE(MIN)

= (0.97)(R

SENSE(NOM)

) = 9.47mΩ. Thus, the sense

resistor's maximum power dissipation is:

MAX

= (5.8A)

× (9.47mΩ) = 0.319W

A 0.5W sense resistor is a good choice in this application.

When the MIC2587/MIC2587R’s foldback current limiting

circuit is engaged in the above example, the current limit

would nominally fold back to 1.23A when the output is

shorted to ground.

PCB Layout Recommendations

4-Wire Kelvin Sensing

Because of the low value typically required for the sense

resistor, special care must be used to accurately measure

the voltage drop across it. Specifically, the measurement

technique across R

SENSE

must employ 4-wire Kelvin

sensing. This is simply a means of ensuring that any

voltage drops in the power traces connected to the

resistors are not picked up by the signal conductors

measuring the voltages across the sense resistors.

Figure 6 illustrates how to implement 4-wire Kelvin

sensing. As the figure shows, all the high current in the

circuit (from V

through R

SENSE

and then to the drain of the

N-channel power MOSFET) flows directly through the

power PCB traces and through R

SENSE

. The voltage drop

across R

SENSE

is sampled in such a way that the high

currents through the power traces will not introduce

significant parasitic voltage drops in the sense leads. It is

recommended to connect the hot swap controller's sense

leads directly to the sense resistor's metalized contact

pads. The Kelvin sense signal traces should be

symmetrical with equal length and width, kept as short as

possible and isolated from any noisy signals and planes.

Additionally, for designs that implement Kelvin sense

connections that exceed 1” in length and/or if the Kelvin

(signal) traces are vulnerable to noise possibly being

injected onto these signals, the example circuit shown in

Figure 7 can be implemented to combat noisy

environments. This circuit implements a 1.6 MHz low-

pass filter to attenuate higher frequency disturbances on

the current sensing circuitry. However, individual system

analysis should be used to determine if filtering is

necessary and to select the appropriate cutoff frequency

for each specific application.

Other Layout Considerations

Figure 8 is a recommended PCB layout diagram for the

MIC2587-2BM. Many hot swap applications will require

load currents of several amperes. Therefore, the power

and Return) trace widths (W) need to be wide enough

to allow the current to flow while the rise in temperature for

a given copper plate (e.g., 1oz. or 2oz.) is kept to a

maximum of 10°C to 25°C. Also, these traces should be

as short as possible in order to minimize the IR drops

between the input and the load. The feedback network

resistor values in Figure 8 are selected for a +24V

application. The resistors for the feedback (FB) and ON

pin networks should be placed close to the controller and

the associated traces should be as short as possible to

improve the circuit’s noise immunity. The input “clamping

diode” (D1) is referenced in the “Typical Application Circuit”

on Page 1. If possible, use high-frequency PCB layout

techniques around the GATE circuitry (shown in the

“Typical Application Circuit”) and use a dummy resistor

(e.g., R3 = 0Ω) during the prototype phase. If R3 is

needed to eliminate high-frequency oscillations, common

values for R3 range between 4.7Ω to 20Ω for various

power MOSFETs. Finally, the use of plated-through vias

will be needed to make circuit connection to the power and

ground planes when utilizing multi-layer PCBs.

MOSFET and Sense Resistor Vendors

Device types, part numbers, and manufacturer contacts for

power MOSFETs and sense resistors are provided in

Table 1.

Micrel MIC2587/MIC2587R

October 2004 14

M9999-102204

(408) 955-1690

Figure 6. 4-Wire Kelvin Sense Connections for R

SENSE

Figure 7. Current Limit Sense Filter for Noisy

Systems

Figure 8. Recommend ed PCB Layout for Sense Resisto r,

Power MOSFET, Timer and Feedback Network.

Micrel MIC2587/MIC2587R

October 2004 15

M9999-102204

(408) 955-1690

MOSFET Vendors Key MOSFET Type(s) Breakdown Vo ltag e (V

DSS

) Contact Information

SUM75N06-09L (TO-263)

SUM70N06-11 (TO-263)

SUM50N06-16L (TO-263)

60V

www.siliconix.com

(203) 452-5664

Vishay - Siliconix SUP85N10-10 (T O-220AB)

SUB85N10-10 (TO- 263)

SUM110N10-09 (TO-263)

SUM60N10-17 (TO-263)

100V

www.siliconix.com

(203) 452-5664

International Rectifier IRF530 (TO-220AB)

IRF540N (TO-220AB) 100V

100V www.irf.com

(310) 322-3331

Renesas 2SK1298 (TO-3PFM)

2SK1302 (TO-220AB)

2SK1304 (TO-3P)

60V

100V

www.renesas.com

(408) 433-1990

Resistor Vendors Sense Resistors Contact Information

Vishay - Dale “WSL” and “WSR” Series www.vishay.com/docswsl_30100.pdf

(203) 452-5664

IRC “OARS” Series

“LR” Series

second source to “WSL”

www.irctt.com/pdf_files/OARS.pdf

www.irctt.com/pdf_files/LRC.pdf

(828) 264-8861

Table 1. MOSFET and Sen se Resistor Vendors

Micrel MIC2587/MIC2587R

October 2004 16

M9999-102204

(408) 955-1690

Package Information

8-Pin SOIC (M)

MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA

TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http:/www.micrel.com

The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its use.

Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.

Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can

reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the

body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser’s use or

sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to fully indemnify Micrel for any

damages resulting from such use or sale.