MIC2044 [MICREL]
SINGLE CHANNEL HIGH CURRENT LOW VOLTAGE, PROTECTED POWER DISTRIBUTION SWITCH; 单路高电流低电压保护的电源分配开关型号: | MIC2044 |
厂家: | MICREL SEMICONDUCTOR |
描述: | SINGLE CHANNEL HIGH CURRENT LOW VOLTAGE, PROTECTED POWER DISTRIBUTION SWITCH |
文件: | 总15页 (文件大小:268K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
MIC2044/2045
Single Channel, High Current, Low Voltage,
Protected Power Distribution Switch
General Description
Features
TheMIC2044andMIC2045arehigh-sideMOSFETswitches
optimizedforgeneralpurposepowerdistributionapplications
that require circuit protection. These devices switch up to
5.5V and as low as 0.8V while offering both programmable
current limiting and thermal shutdown to protect the device
and the load. A fault status output is provided to indicate
overcurrent and thermal shutdown fault conditions. Both
devices employ soft-start circuitry to minimize the inrush
current in applications that employ highly capacitive loads.
Additionally, fortightercontroloverinrushcurrentduringstart
up, the output slew-rate may be adjusted by an external
capacitor.
• 30mΩ maximum on-resistance
• 0.8V to 5.5V operating range
• Adjustable current limit
• Up to 6A continuous output current
• Short circuit protection
• Very fast reaction to short circuits
• Thermal shutdown
• Adjustable slew-rate control
• Circuit breaker mode (MIC2045)
• Fault status flag
• Power-Good detection
• Undervoltage lockout
• No reverse current flow through the switching MOSFET
when OFF or disabled
• Low quiescent current
TheMIC2045featuresaauto-resetcircuitbreakerthatlatches
the output OFF upon detecting an overcurrent condition
lasting more than 32ms. The output is reset by removing or
reducing the load.
Applications
• Docking stations
• LAN servers
Data sheets and support documentation can be found on
Micrel’s web site at www.micrel.com.
• WAN switches
• Hot swap board insertions
• Notebook PCs
• PDAs
• Base stations
• RAID controllers
• USB hosts
Typical Application
"Applications Information."
Micrel, Inc. • 1849 Fortune Drive • San Jose, CA 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 944-0970 • http://www.micrel.com
October 2003
1
MIC2044/2045
MIC2044/2045
Micrel
Ordering Information
Part Number
Enable
Circuit Breaker
Package
MIC2044-1BTS
MIC2044-2BTS
MIC2045-1BTS
MIC2045-2BTS
Active-High
Active-Low
Active-High
Active-Low
16-Pin TSSOP
16-Pin TSSOP
16-Pin TSSOP
16-Pin TSSOP
X
X
Pin Configuration
PWRGD
1
2
3
4
5
6
7
8
16 VIN
EN
/FAULT
SLEW
UVLOIN
ILIM
15 PGREF
14 VOUT
13 VIN
12 VOUT
11 VIN
VIN
10 GND
VBIAS
9 VOUT
MIC2044/MIC2045
16-Pin TSSOP (TS)
MIC2044/2045
2
October 2003
MIC2044/2045
Micrel
Pin Description
Pin Number
Pin Name
Pin Function
1
PWRGD
Power-Good (Output): Open drain N-Channel device, active high. This pin
asserts high when the voltage at PGREF exceeds its threshold.
2
3
EN
Switch Enable (Input): Gate control pin of the output MOSFET available as
an active high (–1) or active low (–2) input signal.
/FAULT
Fault Status (Output): Open drain N-Channel device, active low. This pin
indicates an overcurrent or thermal shutdown condition. For an overcurrent
event, /FAULT is asserted if the duration of the overcurrent condition lasts
longer than 32ms.
10
4
GND
Ground connection: Tie to analog ground.
SLEW
Slew-Rate Control (Input): A capacitor connected between this pin and
ground will reduce (slow) the output slew-rate. The output turn-on time must
be less than the nominal flag delay of 32ms in order to avoid nuisance
tripping of the /FAULT output since VOUT must be “fully on” (i.e., within
200mV of the voltage at the input) before the /FAULT signal delay elapses.
The slew-rate limiting capacitor requires a 16V rating or greater, 25V is
recommended. See “Applications Information: Output Slew-Rate Adjust-
ment” for further details.
6
5
ILIM
Current Limit (Input): A resistor (RSET) connected from this pin to ground
sets the current limit threshold as ILIMIT = CLF/RSET. CLF is the current limit
factor specified in the “Electrical Characteristics” table. For the MIC2044/45,
the continuous output current range is 1A to 6A.
UVLOIN
Undervoltage Lockout Adjust (Input): With this pin left open, the UVLO
threshold is internally set to 1.45V. When the switching voltage (V ) is at or
IN
below 1.5V, connecting an external resistive divider to this input will lower the
UVLO threshold. The total resistance of the divider must be less than 200kΩ.
To disable the UVLO, tie this pin to VIN. See “Applications Information” for
further detail.
7,11,13,16
VIN
Switch Supply (Input): Connected to the drain of the output MOSFET. The
range of input for the switch is 0.8V to 5.5V. These pins must be externally
connected together to achieve rated performance.
9,12,14
8
VOUT
VBIAS
Switch (Output): Connected to the source of the output MOSFET. These
pins must be externally connected together to achieve rated performance.
Bias Supply (Input): This input pin supplies power to operate the switch and
internal circuitry. The input range for VBIAS is 1.6V to 5.5V. When switched
voltage (VIN) is between 1.6V to 5.5V and the use of a single supply is
desired, connect VBIAS to VIN externally.
15
PGREF
Power-Good Threshold (Input): Analog reference used to specify the
PWRGD threshold. When the voltage at this pin exceeds its threshold, VTH
PWRGD is asserted high. An external resistive divider network is used to
determine the output voltage level at which VTH is exceeded. See the
“Functional Description” for further detail. When the PWRGD signal is not
utilized, this input should be tied to VOUT.
,
October 2003
3
MIC2044/2045
MIC2044/2045
Micrel
Absolute Maximum Ratings (Note 1)
Operating Ratings (Note 2)
V
and V
.................................................................................. 6V
Supply Voltage
IN
BIAS
V
............................................................... 0.8V to 5.5V
/FAULT, PWRGD Output Voltage ...................................6V
/FAULT, PWRGD Output Current .............................. 25mA
IN
V
........................................................... 1.6V to 5.5V
BIAS
Continuous Output Current ................................... 1A to 6A
ESD Rating, Note 3
Human Body Model................................................... 2kV
Machine Model ........................................................200V
Ambient Temperature (T ) ........................... –40°C to 85°C
A
Package Thermal Resistance (R
)
θ(J-A)
TSSOP ................................................................85°C/W
Electrical Characteristics (Note 4)
VIN = VBIAS = 5V, TA = 25°C unless specified otherwise. Bold indicates –40°C to +85°C.
Symbol
VIN
Parameter
Condition
IN ≤ VBIAS
Min
0.8
1.6
Typ
Max
5.5
Units
Switch Input Voltage
Bias Supply Voltage
VBIAS Supply Current - Switch OFF
V
V
V
VBIAS
IBIAS
5.5
No load
No load
0.1
300
5
400
µA
µA
VBIAS Supply Current - Switch ON
Note 5
VEN
Enable Input Voltage
VIL(max)
VIH(min)
2.4
2.5
100
.01
20
1.5
V
V
3.5
–1
VENHYST
IEN
Enable Input Threshold Hysteresis
Enable Input Current
mV
µA
mΩ
VEN = 0V to 5.5V
1
RDS(ON)
Switch Resistance
VIN = VBIAS = 3V, 5V
IOUT = 500mA
30
ILEAK
CLF
Output Leakage Current
Output off
10
µA
Current Limit Factor
Note 6
VIN = 3V, 5V, 0.5V ≤ VOUT < 0.5VIN
300
215
380
460
A•Ω
1A ≤ IOUT ≤ 6A
VTH
PGREF Threshold
VIN = VBIAS = 1.6V to 5.5V
230
245
mV
V
VLATCH
Output Reset Threshold
VIN = 0.8V to 5.5V
VIN–.0.2
VOUT rising (MIC2045)
ILATCH
VOL
Latched Output Off Current
Output latched off (MIC2045)
1
3
5
mA
V
Output Low Voltage
(/FAULT, PWRGD)
IOL (/FAULT) = 15mA
IOL (PWRGD) = 5mA
0.4
IOFF
VUV
/FAULT, PWRGD Off Current
VFAULT = VPWRGD = 5V
1
µA
Undervoltage Lockout Threshold
VIN rising
VIN falling
1.30
1.20
1.45
1.35
1.58
1.50
V
V
VUVHYST
VUVINTH
Undervoltage Lockout
Threshold Hysteresis
100
mV
UVLO Adjust Pin Threshold Voltage VIN rising
VIN falling
200
185
230
215
260
245
mV
mV
VUVINHYST
UVLO Adjust Pin Threshold Hysteresis
15
mV
Overtemperature Threshold
TJ increasing
TJ decreasing
140
120
°C
°C
MIC2044/2045
4
October 2003
MIC2044/2045
Micrel
Symbol
tFLAG
tON
Parameter
Condition
Min
25
Typ
32
1
Max
40
Units
ms
ms
ms
µs
Flag Response Delay
Output Turn-on Delay
Output Turn-on Rise Time
Output Turn-off Delay
Output Turn-off Fall Time
VIN = VBIAS = 3V, 5V
RLOAD = 10Ω, CLOAD = 1µF
RLOAD = 10Ω, CLOAD = 1µF
RLOAD = 10Ω, CLOAD = 1µF
RLOAD = 10Ω, CLOAD = 1µF
0.75
1.5
1.25
3.5
5
tR
2.5
1
tOFF
tF
24
µs
Note 1. Exceeding the absolute maximum rating may damage the device.
Note 2. The device is not guaranteed to function outside its operating rating.
Note 3. Devices are ESD sensitive. Handling precautions recommended. Human body model: 1.5kΩ in series with 100pF.
Note 4. Specification for packaged product only.
Note 5. OFF is V < 1.0V for MIC2044/MIC2045–1 and V > 4.0V for MIC2044/MIC2045 –2. ON is V > 4.0V for MIC2044/MIC2045–1 and
EN
EN
EN
V
< 1.0V for MIC2044/MIC2045 –2.
EN
Note 6. The current limit is determined as follows: I
= CLF/R
.
SET
LIM
Timing Diagrams
tOFF
50%
0
0
VEN
tON
90%
10%
VOUT
(a) MIC2044/45-1
50%
0
0
VEN
tOFF
tON
90%
10%
(b) MIC2044/45-2
VOUT
Figure 1. Turn-On/Turn-Off Delay
Increase the load
0
0
VEN
VIN 0.2V
VOUT
ILIMIT
0
IOUT
tFLAG
0
/FAULT
Figure 2. Overcurrent Fault Response — MIC2044-2
October 2003
5
MIC2044/2045
MIC2044/2045
Micrel
Test Circuit
C1
0.1µF
VDD
C2
0.1µF
ILOAD
MIC2044/45-xBTS
8
9,12,14
VBIAS
VOUT
VOUT
R1
20kΩ
R5
260kΩ
CLOAD
47µF
7, 11,
15
13, 16
VIN
VIN
PGREF
C3
10µF
R6
24kΩ
2
R2
20kΩ
EN
R7
20kΩ
R3
3
5
4
/FAULT
75kΩ
1
6
UVLOIN PWRGD
R4
68kΩ
SLEW
GND
ILIM
10
*RSET
*CSLEW
*RSET and CSLEW use multiple values
(See specific response plots)
MIC2044/2045
6
October 2003
MIC2044/2045
Micrel
Typical Characteristics
Enable Input Threshold
(Falling)
Enable Input Threshold
(Rising)
Supply Current
vs. Temperature
vs. Temperature
vs. Temperature
5
4
3
2
1
0
300
5
4
3
2
1
0
275
VIN = VBIAS = 5.5V
250
VBIAS = 5.5V
VBIAS = 5.5V
225
VIN = VBIAS = 3V
200
175
150
VBIAS = 3V
VBIAS = 3V
VBIAS = 1.6V
VBIAS = 1.6V
VIN = VBIAS = 1.6V
125
100
-40 -20
0
20 40 60 80 100
-40 -20
0
20 40 60 80 100
-40 -20
0
20 40 60 80 100
TEMPERATURE (°C)
TEMPERATURE (°C)
TEMPERATURE (°C)
Power-Good Reference
Threshold
ON Resistance
Output Leakage Current
vs. Temperature
vs. Temperature
vs. Temperature
40
35
30
25
20
15
10
5
2500
2250
2000
1750
1500
1250
1000
750
230
225
220
215
210
VIN = V
= 1.6V
BIAS
VBIAS = 5.5V
VIN = V
= 3V
BIAS
VBIAS = 3V
VTH @ 1.6V to 5.5V
VIN = V
= 5.5V
BIAS
500
250
VBIAS = 1.6V
0
0
-40 -20
0
20 40 60 80 100
-40 -20
0
20 40 60 80 100
-40 -20
0
20 40 60 80 100
TEMPERATURE (°C)
TEMPERATURE (°C)
TEMPERATURE (°C)
V
Reverse Current Flow
Turn On Delay
BIAS
Flag Response Delay
vs. Temperature
vs. Temperature
vs. Output Voltage
1600
1400
1200
1000
800
25
50
45
40
35
30
25
20
20
15
10
5
VIN = VBIAS = 5.5V
VIN = VBIAS = 3V
TFLAG = 5V
600
TFLAG = 3V
VIN = GND
VBIAS = 1.6V
VIN = VBIAS = 1.6V
400
200
0
-40 -20
0
20 40 60 80 100
0
1
2
3
–V
4
5
6
-40 -20
0
20 40 60 80 100
TEMPERATURE (°C)
V
(V)
TEMPERATURE (°C)
OUT
BIAS
UVLO Threshold
vs. Temperature
UVLO Adjust Pin Threshold
vs. Temperature
SLEW Voltage
vs. Temperature
3
2.5
2
400
25
20
15
10
5
350
300
250
200
150
100
50
VIN = V
= 5V
BIAS
UVLOIN+
UVLO+
1.5
1
VIN = V
= 3V
BIAS
UVLOIN–
UVLO–
0.5
VIN = V
= 1.6V
BIAS
0
0
0
-40 -20
0
20 40 60 80 100
-40 -20
0
20 40 60 80 100
-40 -20
0
20 40 60 80 100
TEMPERATURE (°C)
TEMPERATURE (°C)
TEMPERATURE (°C)
October 2003
7
MIC2044/2045
MIC2044/2045
Micrel
Functional Characteristics
Latched Output
MIC2045
Latched Output Reset
MIC2045
4.82V
VIN = VBIAS = 5.0V
RLOAD toggles from 2Ω to OPEN
CLOAD = 47µF
VIN = VBIAS = 5.0V
RSET = 220Ω
RLOAD = 1.8Ω
CLOAD = 47µF
RSET = 220Ω
TIME (5ms/div.)
TIME (50ms/div.)
Current Limit Response
UVLO Response
1.45V
VIN = VBIAS = 5.0V
VIN ramps 0V to 1.8V
RLOAD = 5Ω
RLOAD = 1.2Ω
CLOAD = 47µF
RSET = 100Ω
CLOAD = 47µF
RSET = 220Ω
TIME (5ms/div.)
TIME (2.5ms/div.)
MIC2044/2045
8
October 2003
MIC2044/2045
Micrel
Functional Characteristics (continued)
Output Slew Response
Thermal Shutdown Response
VIN = 5.0V
RLOAD = 5Ω
VIN = VBIAS 5.0V
CLOAD = 47µF
CSLEW = 0.033µF
RSET = 220Ω
RLOAD = 2Ω
CLOAD = 47µF
RSET = 220Ω
TIME (2.5ms/div.)
TIME (100ms/div.)
October 2003
9
MIC2044/2045
MIC2044/2045
Micrel
Functional Diagram
MIC2044/2045
10
October 2003
MIC2044/2045
Micrel
Programmable Current Limit
Functional Description
The MIC2044/45 is designed to prevent damage to the
external load by limiting the maximum amount of current it
can draw. The current limit is programmed by an external
TheMIC2044andMIC2045arehigh-sideN-Channelswitches
equipped with programmable current limit up to 6A for use in
generalpurposepowerdistributionapplications.Theswitches,
availablewithactive-highoractive-lowenableinputs,provide
output slew-rate control and circuit protection via thermal
shutdown and an optional output latch during overcurrent
conditions.
resistor (R
) connected from ILIM (Pin 6) to ground and
SET
becomes active when the output voltage is at least 200mV
below the voltage at the input to the device. The limiting
current value is defined by the current limit factor (CLF)
divided by R
, and the MIC2044/45 will limit from 1A to 6A
SET
Input and Output
with a set point accuracy of ±21%. In programming the
VBIAS supplies power to the internal circuitry of the switch
and must be present for the switch to operate. VIN is con-
nectedtothedrainoftheoutputMOSFETandsourcespower
totheswitchedload.VINmustbelessthanorequaltoVBIAS.
VOUT is the source terminal of the output MOSFET and
attachestotheload. Inatypicalcircuit, currentflowsfromVIN
toVOUTtowardtheload. IfVOUTisgreaterthanVIN, current
will flow from VOUT to VIN since the switch is bi-directional
whenthedeviceisenabled. Whendisabled(OFF), theswitch
will block current flow from either direction.
nominal current limit, the value of R
the following equation:
is determined using
SET
380A × Ω
CLF
(
=
)
RSET
=
(1)
ILIMIT
ILIMIT
Andgiventhe±21%toleranceofthecurrentlimitfactor(CLF),
the external resistor is bound by:
50Ω ≤ R
≤ 460Ω
(2)
SET
The graphs below (Figure 3) display the current limit factor
characteristic over the full temperature range at the indicated
voltage. These curves can be used as a point of reference in
determining the maximum variation in the device’s current
Enable Input
Enable, the ON/OFF control for the output switch, is a digital
input available as an active-high (–1) or active-low (–2)
signal. TheEN pin, referenced to approximately 0.5× VBIAS,
must be driven to a clearly defined logic high or logic low.
Failure to observe this requirement, or allowing EN to float,
will cause the MIC2044/45 to exhibit unpredictable behavior.
EN should not be allowed to go negative with respect to
ground, nor allowed to exceed VBIAS. Failure to adhere to
these conditions may result in damage to the device.
limit over the full temperature range. For example: With V
IN
= V
= 3.0V and a nominal 4A current limit (R
= 95Ω),
BIAS
SET
the low and high current limit settings for the MIC2044/45
would be 3.15A and 4.85A, respectively, as shown on the 3V
graph using the 95Ω reference point.
When current limiting occurs, the MIC2044 and MIC2045
respond differently. Upon first reaching the limiting current
both devices restrict current flow, allowing the load voltage to
Undervoltage Lockout
dropbelowV . IftheV toV differentialvoltageexceeds
IN
IN
OUT
When the switch is enabled, undervoltage lockout (UVLO)
200mV, then a fault condition is declared and the fault delay
timer is started. If the fault condition persists longer than the
delay period, typically 32ms, then the /FAULT output asserts
low. At this point, the MIC2044 will continue to supply current
monitors the input voltage, V , and prevents the output
IN
MOSFET from turning on until V exceeds a predetermined
IN
level, nominally set at 1.45V. The UVLO threshold is adjust-
ableandcanbevariedbyapplyinganexternalresistordivider
to the UVLOIN pin from VIN to GND. The resistive divider
networkisrequiredwhentheinputvoltageisbelow1.5V. The
UVLO threshold is internally preset to 1.45V if the UVLOIN
pin is left open. See “Applications Information.”
to the load at the limiting value (I
will latch off its output.
), whereas the MIC2045
LIMIT
Current Limit
Current Limit
vs. R
vs. R
SET
SET
8
8
–40°C to +85°C
–40°C to +85°C
IN = VBIAS = 1.6V
7
7
6
5
4
3
2
1
0
VIN = VBIAS = 3V, 5V
V
6
5
4
CLF (HI)
CLF (HI)
3
2
CLF (LO)
1
CLF (LO)
50 100150200250300350400450
(Ω)
0
0
50 100150200250300350400450
(Ω)
0
R
R
SET
SET
Figure 3. Current Limit Factor
October 2003
11
MIC2044/2045
MIC2044/2045
Micrel
Open Load Detection
/FAULT
TheMIC2045willautomaticallyresetitsoutputwhenthefault
load is cleared. This is accomplished by applying a small
current to VOUT and watching for the voltage at VOUT to rise
to within 200mV of VIN. This current is supplied by an internal
resistor connected to VIN and is connected to VOUT when
MIC2045 latches off.
The /FAULT signal is an N-Channel, open-drain MOSFET
output. An external pull-up resistor tied to a maximum 6V rail
is required for the /FAULT pin. The /FAULT pin is asserted
(active-low) when either an overcurrent or thermal shutdown
conditionoccurs. DuringahotinsertofaPCBorwhenturning
on into a highly capacitive load, the resulting high transient
inrush current may exceed the current limit threshold of the
MIC2044/45. In the case where an overcurrent condition
occurs, /FAULT will assert only after the flag delay time has
elapsed, typically 32ms. This ensures that /FAULT is as-
serted only upon valid overcurrent conditions and that nui-
sance error reporting is prevented.
Power-Good Detection
TheMIC2044/45candetectwhentheoutputvoltageisabove
orbelowapresetthresholdthatismonitoredbyacomparator
at the PGREF input. The PWRGD signal is an N-Channel
open-drain MOSFET output and an external pull-up resistor
up to a 6V maximum rail is required for the PWRGD pin.
Whenever the voltage at the PGREF pin exceeds its thresh-
Thermal Shutdown
old (V ), typically 230mV, the PWRGD output is asserted.
For the MIC2044, thermal shutdown is employed to protect
the device from damage should the die temperature exceed
safe margins due to a short circuit or an excessive load.
Thermal shutdown shuts off the output MOSFET and asserts
the /FAULT output if the die temperature exceeds 140°C.
The MIC2044 automatically resets its output and resumes
supplying current to the load when the die temperature drops
to 120°C. If the fault is still present, the MIC2044 will quickly
re-heat and shut down again. This process of turning
ON-OFF-ON is called thermal cycling and will continue as
long as the power switch is enabled while the fault or
excessive load is present.
TH
Usingthetypicalapplicationscircuitfrompage1thatswitches
3.3V as an example, the output voltage threshold determin-
ing “power is good” is calculated by the following equation:
R2
VOUT(GOOD) = VTH × 1+
(3)
R3
In substituting the resistor values of the circuit and the typical
PGREF threshold, the resulting V is calculated as
OUT(GOOD)
3.0V for this 3.3V switching application.
SLEW
The MIC2044/45’s output rise time is controlled at turn-on to
a minimum of 1.5ms and is controlled by an internal slew-rate
limiting circuit. A slew-rate adjustment control pin is available
for applications requiring slower rise times. By placing a
capacitor between SLEW and ground, longer rise times can
beachieved.Forfurtherdetail,seethe“ApplicationsInforma-
tion” section.
Depending on PCB layout (including thermal considerations
such as heat sinking), package, and ambient temperature, it
may take several hundred milliseconds from the incidence of
the fault to the output MOSFET being shut off.
Circuit Breaker Function (MIC2045)
The MIC2045 is designed to shut off all power to the load
when a fault condition occurs, just as a circuit breaker would
do. In this case, a fault condition is deemed to be anytime the
output current exceeds the current limit for more than the flag
delay period, nominally 32ms. Once the output shuts off, it
remains off until either the fault load is removed from VOUT
or the EN input is cycled ON-OFF-ON. If the fault is still
present after EN has been cycled, the MIC2045 will again
shut off all power to the load after 32ms. Once the fault has
been removed, then normal operation will resume.
MIC2044/2045
12
October 2003
MIC2044/2045
Micrel
a non-linear response. See the “Functional Characteristics”
section. Table 1 shows the rise time for various standard
capacitor values. Additionally, the output turn-on time must
be less than the nominal flag delay of 32ms in order to avoid
nuisance tripping of the /FAULT output. This limit is imposed
by the current limiting circuitry which monitors the
(VIN – VOUT) differential voltage and concludes a fault
condition is present if the differential voltage exceeds 200mV
for more than the flag delay period. For the MIC2045, the
/FAULT will assert and the output will latch off if the output is
not within 200mV of the input before the flag delay times out.
When using the active-low (–2) option with the EN input tied
to ground, slew control is functional during initial start-up but
does not function upon resetting the input power to the
device. In order for the SLEW control to operate during
consecutive system restarts, the EN pin must reset (toggle
OFF to ON).
Applications Information
Input and Output
Supply Bypass Filtering
The need for input supply bypass is brought about due to
several factors, most notably the input/output inductance
along the power path, operating current and current limit, and
output capacitance. A 0.1µF to 0.47µF bypass capacitor
positioned very close to the VIN pin to GND of the device is
strongly recommended to filter high frequency oscillations
due to inductance. Also, a sufficient bypass capacitor posi-
tioned close to the input source to the switch is strongly
advised in order to suppress supply transient spikes and to
limit input voltage droop. Inrush current increases with larger
output capacitance, thus the minimum value of this capacitor
willrequireexperimentaldeterminationfortheintendedappli-
cation and design. A good starting point is a capacitor
between 4.7µF to 15µF. Without these bypass capacitors, an
extreme overload condition such as a short circuit, or a large
capacitive load, may cause either the input supply to exceed
the maximum rating of 6V and possibly cause damage to the
internal control circuitry or allow the input supply to droop and
fall out of regulation and/or below the minimum operating
voltage of the device.
UVLO Threshold Setting With Low Input Voltages
When the switching voltage is below 1.6V, the device’s
standard UVLO threshold (1.45V nominal) will hinder the
output MOSFET in switching VIN to VOUT. In this case, the
use of the UVLOIN pin is required to override the standard
UVLO threshold and set a new, lower threshold for the lower
input voltage. An external resistive divider network con-
nected at the UVLOIN pin is used to set the new threshold.
Due to the ratio of the internal components, the total series
resistance of the external resistive divider should not exceed
200kΩ. ThecircuitshowninFigure4illustratesanapplication
that switches 0.8V while the device is powered from a
separate 2.5V power supply. The UVLO threshold is set by
the following equation.
Output Capacitance
WhentheMIC2044dieexceedstheovertemperaturethresh-
old of approximately 140°C, the device can enter into a
thermal shutdown mode if the die temperature falls below
120°C and then rises above 140°C in a continuous cycle.
With VOUT cycling on and off, the MIC2044 will reset the
/FAULT while in an overtemperature fault condition if V
is
OUT
allowed to swing below ground. The inductance present at
the output must be neutralized by capacitance in order to
ensure that the output does not fall below ground. In order to
counter the board parasitic inductance and the inductance of
relativelyshort-lengthpowercable(≤1ft.,16-20gaugewire),
a minimum output capacitance of 22µF is strongly recom-
mended and should be placed close to the VOUT pin of the
MIC2044. For applications that use more than a foot of cable,
an additional 10µF/ft. is recommended.
R2
V
= 0.23V × 1+
(4)
UVTH
R3
In substituting the resistor values from Figure 4, the resulting
UVLO threshold (V ) is calculated as 0.6V for this 0.8V
UVTH
switching application. When using the UVLOIN pin to set a
new UVLO threshold, an optional 0.1µF to 1.0µF capacitor
from UVLOIN to GND may be used as a glitch filter in order
to avoid nuisance tripping of the UVLO threshold. If the
UVLOIN pin is not in use, this pin should be left open
(floating). The use of a pull-down resistor to ground will offset
the ratio of the internal resistive divider to this pin resulting in
a shift in the UVLO threshold. To bypass (disable) UVLO,
connect the UVLOIN pin directly to the VIN pin of the
MIC2044/45.
Reverse Current Blocking
The MIC2044/45 provides reverse current flow blocking
through the output MOSFET if the voltage at VOUT is greater
than VIN when the device is disabled. The V
supply has
BIAS
a limited reverse current flow if the voltage at VOUT is pulled
above VBIAS when the device is disabled. A graph of the
V
reverse current flow is shown in the “Functional
BIAS
Characteristics” section. The reverse current for VBIAS can
be completely blocked by inserting a Schottky diode from the
VBIAS pin (cathode) to the supply (anode). However, the
minimum voltage of 1.6V must be supplied to VBIAS after
accounting for the voltage drop across the diode.
Conditions: V = V
= 5V/3V
BIAS
IN
C
= 47µF; I
= 1A
LOAD
LOAD
C
(µF)
Rise Time (ms)
SLEW
5V
3V
6.6
Output Slew-Rate Adjustment
0.02
4.4
7.5
11
Theoutputslew-ratefortheMIC2044/45canbesloweddown
by the use of a capacitor (16V rating, minimum; 25V sug-
gested) between SLEW and GND. The slew-rate control
circuitry is independent of the load capacitance and exhibits
0.033
0.047
0.1
11.25
16
24
31.5
Table 1. Typical Output Rise Time for Various C
SLEW
(V = 5V, 3V)
IN
October 2003
13
MIC2044/2045
MIC2044/2045
Micrel
Figure 4. Lower UVLO Setting
Power Dissipation
1. Supply additional copper area under the device
Power dissipation depends on several factors such as the
load, PCB layout, ambient temperature, and package type.
The following equations can be used to calculate power
dissipation and die temperature.
to remove heat away from the IC.
See “Application Hint 17” for a general guideline
in calculating the suggested area.
2. Provide additional pad area on the corner pins of
the MIC2044/45 IC for heat distribution.
Calculation of power dissipation can be accomplished by the
following equation:
2
3. Tie the common power pins (V = pins 7, 11,
P = R
× (I )
OUT
(5)
IN
D
DS(on)
13, 16 and V
= pins 9, 12, 14) together in a
OUT
To relate this to junction temperature, the following equation
can be used:
manner such that the traces entering and
leaving the device have a uniform width suffi-
cient for the application’s current requirements
plus added margin (25% minimum recom-
mended).
T = P × R
+ T
A
(6)
J
D
(θJ-A)
where T = junction temperature, T = ambient temperature
J
A
and R
is the thermal resistance of the package.
θ(J-A)
Printed Circuit Board Hot Plug
Ex: For 4A maximum current, design traces for
5A capability.
The MIC2044/45 are ideal inrush current limiting power
switches suitable for hot plug applications. Due to the inte-
grated charge pump, the MIC2044/45 present a high imped-
ance when in the off state and the device slowly becomes a
low impedance as it turns on. This effectively isolates power
supplies from highly capacitive loads by reducing inrush
current during hot plug events. This same feature also can be
used for soft-start requirements.
4. For PCB trace width calculation, there are
numerous calculator programs available on the
internet and elsewhere. As a general rule of
thumb, 15-20 mils width for every 1A of current
when using 1oz. copper. However, the trace
width calculators often take into account maxi-
mum temperature increase constraints, as well
as layer arrangement, in determining the PCB
trace widths. As a reference, the following link is
suggested for trial tests in PCB trace width
PCB Layout Recommendations
The MIC2044 and MIC2045 have very low on-resistance,
typically 20mΩ, and the switches can provide up to 6A of
continuous output current. Under heavy loads, the switched
current may cause the devices to heat up considerably. The
following list contains some useful suggestions for PCB
layout design of the MIC2044/45 in order to prevent the die
from overheating under normal operating conditions.
1
calculations.
http://www.aracnet.com/cgi-usr/gpatrick/trace.pl
1.
Micrel Semiconductor does not assume responsibility for the use of
this program tool in the event that any PCB assembled, tested,
produced, and/or manufactured becomes damaged and/or causes any
degradation of system performance or damage to any system
components in which the aforementioned PCB is included.
MIC2044/2045
14
October 2003
MIC2044/2045
Micrel
Package Information
Rev. 01
16-Pin TSSOP (TS)
MICREL, INC. 1849 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL + 1 (408) 944-0800 FAX + 1 (408) 944-0970 WEB http://www.micrel.com
The information furnished by Micrel in this datasheet 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 at Purchaser’s own risk and Purchaser agrees to fully indemnify
Micrel for any damages resulting from such use or sale.
© 2003 Micrel, Incorporated.
October 2003
15
MIC2044/2045
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