MIC13441.56 MB

MIC1344
Smart, 3A, Two-Channel, Power
ORing Switch
General Description
Features
The MIC1344 is an advanced two input, one output, hot
swappable, power multiplexer. It has both automatic and
manual input selection (ENA and ENB) and four status
outputs.
•
•
•
•
•
•
•
•
•
•
In automatic mode, the MIC1344 will automatically connect
the higher of two input voltages (INA or INB), to the output
(OUT). In manual mode, either of the two inputs can be
routed to the output, or both power inputs can be turned off
so that multiple MIC1344’s can be used for more than two
power inputs.
The MIC1344 has four digital open drain status outputs.
The ASEL\ and BSEL\ outputs indicate which input is
selected. The STAOK and STBOK outputs indicate the
general health of the input channels. Specifically, these
outputs will be inactive (high) if the channel has sufficient
input voltage, the channel current is within acceptable
limits, the die temperature is not too hot, and the channel
has no reverse current detected.
The current limit for each input channel of the MIC1344
can be individually set up to 3A, by two external currentlimit set resistors (ILIMA and ILMIB). The current flowing in
each of the channels can be read by measuring the
voltage at these resistors.
Datasheets and support documentation are available on
Micrel’s web site at: www.micrel.com.
Two input, one output, power ORing switch
Input voltage operating range: 2.8V to 5.5V
Automatic and manual input selection modes
Four digital and two analog status outputs
Current blocking: output-to-input and input-to-input
Low on-resistance (70mΩ typical)
Up to 3A current handling
Low standby channel current (11µA typical)
Separate current limiting and readback for each channel
Available in 12-pin, 2mm × 2mm, QFN (FTQFN)
package
• Thermal-shutdown protection
• −40°C to 125°C junction temperature range
Applications
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Two input to one output power selector
Multiple inputs to a single output power selector
Charger input power selector
Dual battery selector
Main and backup power selector
USB power selector
Portable products
Supercapacitor ORing
Backup battery diode ORing
Typical Application
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
April 24, 2015
Revision 1.0
Micrel, Inc.
MIC1344
Ordering Information
Part Number
Marking
Output Current
Junction Temperature Range
MIC1344YFT
4N
Adjustable (3.0A maximum)
–40°C to +125°C
Package
(1, 2)
12-Pin 2mm × 2mm FTQFN
Notes:
1. Pin 1 indicator = “▲”
2. Green RoHS compliant package. Lead finish is NiPdAu. Mold compound is halogen free.
Pin Configuration
12-Pin 2mm × 2mm FTQFN (FT)
(Top View)
Pin Description
Pin Number
Pin Name
1
INB
Pin Function
Supply Voltage Input B. This input may be bypassed to GND with >0.1µF, X7R or similar, ceramic
type capacitor. This input is hot swappable.
Open drain output, digital status monitor for supply voltage Input B (INB). Voltage will be low if
any of the following conditions occur:
•
INB is below the UVLO limit.
2
STBOK
•
The output current from INB is at its set current limit.
•
The die temperature exceeds the overtemperature limit.
•
Reverse current detected (VOUT > VINB+100mV).
•
Prolonged high hysteresis mode engaged.
3
BSEL\
Open Drain Output. Low if Input B (INB) is providing power to the OUT pin.
4
ILIMB
A resistor from this pin to ground sets the current limit for INB. The current flowing into INB can be
monitored by the voltage on this pin.
5
ENB
The ENA and ENB digital inputs control which voltage input (INA or INB) is connected to the
voltage out (OUT) pin. There is an internal 570kΩ pull-down on this pin to ensure that automatic
select mode is active when the logic that is driving the MIC1344 is being powered up. Table 1
shows how to control the power routing with the ENA and ENB inputs.
6
GND
Ground.
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MIC1344
Pin Description (Continued)
Pin Number
Pin Name
Pin Function
7
ENA
The ENA and ENB digital inputs control which voltage input (INA or INB) is connected to the
voltage out (OUT) pin. There is an internal 570kΩ pull-down on this pin to ensure that automatic
select mode is active when the logic that is driving the MIC1344 is being powered-up. Table 1
shows how to control the power routing with the ENA and ENB inputs.
8
ILIMA
A resistor from this pin to ground sets the current limit for INA. The current flowing into INA can be
monitored by the voltage on this pin.
9
ASEL\
Open Drain Output. Low if Input A (INA) is providing power to the OUT pin.
Open drain output, digital status monitor for supply voltage Input A (INA). Voltage will be low if
any of the following conditions occur:
•
INA is below the UVLO limit.
10
STAOK
•
The output current from INA is at its set current limit.
•
The die temperature exceeds the overtemperature limit.
•
Reverse current detected (VOUT > VINA+100mV).
•
Prolonged high hysteresis mode engaged.
11
INA
Supply Voltage Input A. This input may be bypassed to GND with >0.1µF, X7R or similar, ceramic
type capacitor. This input is hot swappable.
12
OUT
Voltage Output. This is the power output. Bypass this pin to ground with a capacitor suitable to
provide adequate power during the switchover time of the MIC1344. This capacitor should be a
minimum of 10µF, X7R or similar temperature stability, ceramic capacitor.
EP
ePad
Internally connected to electrical ground (GND) pin. Connect to as large a PCB area as practical
to dissipate heat from the MIC1344.
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MIC1344
Absolute Maximum Ratings(3)
Operating Ratings(4)
INA, INB, OUT, ENA, ENB ........................... −0.3V to +6.0V
ASEL\, BSEL\, STAOK, STBOK .................. −0.3V to +6.0V
ILIMA ..................................................... −0.3V to VINA +0.3V
ILIMB ..................................................... −0.3V to VINB +0.3V
(6)
Power Dissipation (PD) ........................... Internally Limited
Lead Temperature (soldering, 10s) ............................ 260°C
Junction Temperature (TJ) ........................ –40°C to +125°C
Storage Temperature (TS) ......................... –65°C to +150°C
ESD Rating.................................................................Note 7
INA, INB .................................................... +2.8V to +5.5V
OUT, ENA, ENB ................................................ 0V to +5.5V
ASEL\, BSEL\, STAOK, STBOK ....................... 0V to +5.5V
ILIMA .....................................................................0V to VINA
ILIMB .....................................................................0V to VINB
Junction Temperature (TJ) ........................ –40°C to +125°C
Junction Thermal Resistance
12-Pin 2mm × 2mm FTQFN:
θJA ............................................................. 77.9°C/W
θJC............................................................. 11.9°C/W
(5)
Electrical Characteristics
VINA or VINB = 5V; IOUT = 100mA; CINA = CINB = 1µF, COUT = 10µF, TJ = +25°C, bold values indicate junction temperature
–40°C to +125°C, unless noted.
Parameter
Supply Current
Condition
Min.
Typ.
Max.
Both inputs disabled, IOUT = 0A. Per channel.
11
15
One of the inputs enabled, IOUT = 0A.
300
350
2.35
2.5
2.2
INA and INB Rising UVLO Voltage
UVLO Hysteresis
INA or INB Switch Resistance
0.1
Units
µA
V
V
IOUT = 500mA.
70
200
VINA or VINB = 2.8V, IOUT = 500mA
120
220
mΩ
mΩ
Output-to-Input Leakage Current
Leakage current of OUT to INA or INB when the
corresponding input channel is turned off.
1
10
µA
Input-to-Input Leakage Current
Leakage current of INA to INB, or INB to INA.
1
10
µA
INA-to-INB or INB-to-INA Switchover
Comparator Hysterisis Voltage
300
mV
ILIMA or ILIMB
Output Current Accuracy (IN = 2.8V)
RILIMA, RILIMB = 931Ω
2.58
2.85
3.15
RILIMA, RILIMB = 10kΩ
0.25
0.28
0.31
ILIMA or ILIMB
Output Current Accuracy (IN = 5.5V)
RILIMA, RILIMB = 931Ω
2.40
2.7
3.00
RILIMA, RILIMB = 10kΩ
0.20
0.25
0.30
INA or INB Reverse Voltage
Shutdown Threshold
VOUT = 2.6V to VINA = 2.5V (with INA selected) or
VOUT = 2.6V to VINB = 2.5V (with INB selected)
100
mV
INA or INB Reverse Voltage
Shutdown Hysteresis
VOUT falling
50
mV
A
A
Notes:
3. Exceeding the absolute maximum ratings may damage the device.
4. The device is not guaranteed to function outside its operating ratings.
5. INA and INB can be taken to 0V; however the minimum operating voltage is 2.8V.
6. The maximum allowable power dissipation of any TA (ambient temperature) is PD(MAX) = (TJ(MAX) – TA) / θJA. Exceeding the maximum allowable power
dissipation will result in excessive die temperature, and the MIC1344 will go into thermal shutdown.
7. Devices are ESD sensitive. Handling precautions recommended. Human Body Model (HBM) is 1.5kΩ in series with 100pF. Machine Model (MM), is
200pF, per JESD 22-A115.
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MIC1344
Electrical Characteristics (Continued)
VINA or VINB = 5V; IOUT = 100mA; CINA = CINB = 1µF, COUT = 10µF, TJ = +25°C, bold values indicate junction temperature
–40°C to +125°C, unless noted.
Parameter
Condition
Min.
Typ.
Max.
Units
ILIMA or ILIMB Current-Limit
(8)
Onset Threshold Voltage
RILIMA, RILIMB = 10kΩ
1.10
1.20
1.30
V
VILIMA or VILIMB for Low-Current
VINA or VINB = 3.5V, IOUT = 20mA
15
100
185
mV
INA or INB High-Load Shutdown
(9)
Response Time
IOUT = 0mA to ROUT = 0.1Ω
(turn off transition time, no load to high-current load)
Automatic Mode Switchover
(10)
Delay Time
Automatic mode, VINA + 300mV ≥ VINB or
VINB + 300mV ≥ VINA
INA-to-INB Manual Mode
(11)
Switchover Delay Time
INB-to-INA Manual Mode
(11)
Switchover Delay Time
Switch Off Delay Time
(12)
(13)
Initial Power-Up Delay
1.5
µs
5
10
µs
Time from INB selected to VOUT = 90% of VINB voltage
VINA = 0V, VINB = 5V
350
700
µs
Time from INA selected to VOUT = 90% of VINA voltage
VINA = 5V, VINB = 0V
350
700
µs
Automatic mode, INA or INB selected to No Input
Selected. ROUT = 10Ω. No COUT
0.5
Automatic mode, INA or INB selected. ROUT = 10Ω,
VINA or VINB transitions from 0V to 5V
0.3
ENA or ENB Input Resistance
µs
1
ms
570
kΩ
5V ENA or ENB Logic Level Low
Voltage
Voltage falling. VINA or VINB = 5V.
1.20
1.05
V
3V ENA or ENB Logic Level Low
Voltage
Voltage falling. VINA or VINB = 3V.
0.8
0.60
V
5V ENA or ENB Threshold Hysteresis
VINA or VINB = 5V.
300
STAOK or STBOK Active, Output
Voltage
ISTAOK or ISTBOK = 10mA
0.15
STAOK or STBOK Inactive,
Leakage Current
VSTAOK or VSTBOK = 5V (leakage current to GND)
ASEL\ or BSEL\ Active, Output Voltage
IASEL\ or IBSEL\ = 10mA
ASEL\ or BSEL\ Inactive, Leakage
Current
VASEL\ or VBSEL\ = 5V (leakage current to GND)
Overtemperature Shutdown
Temperature Threshold
Junction temperature increasing
0.3
1
0.15
Overtemperature Shutdown Hysteresis
mV
V
µA
0.3
V
1
µA
150
°C
20
°C
Notes:
8. The current-limit threshold onset voltage is the voltage on ILIM (A or B) that corresponds to the onset of the output current regulation for the
corresponding input channel.
9. The time it takes for the output current on either INA or INB to go from 0mA (no load) to 20% over the steady state maximum current-limit value,
when a load of 0.1Ω is applied between the OUT pin and GND.
10. This is the time that the MIC1344 takes to switch between one of the two input voltages when it is in automatic mode. This is the time from when one
of the input voltages goes above the other by 300mV, to the time when the output voltage reaches 90% of its final value.
11. This is the time it takes to switch from one input (INA or INB) to the other (INB or INA), when in manual mode. This is the time from the ENx
transition, to when the output voltage reaches 90% of its final value. (x can be either A, or B).
12. This is the time from the ENA = 0, ENB = 1 transition, to when the output voltage reaches 10% of its initial value.
13. This is the time between when the MIC1344 is powered up (10% of the VINA or VINB voltage ramp-up), to the time when the OUT voltage stabilizes to
within 90% of its final value.
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Micrel, Inc.
MIC1344
Typical Characteristics
Supply Current
vs. Input Voltage
Supply Current
vs. Temperature
300
300
200
150
100
200
150
VINA OR VINB = 5V
100
NO INPUT
SELECTED
NO INPUT
SELECTED
50
50
0
0
0
1
2
3
4
5
-25
0
25
50
75
100
IN (V)
TEMPERATURE (°C)
Switch-On Resistance
vs. Temperature
VINA to VINB or VINB to VINA
Leakage vs. Temperature
60
CHANNEL A OR CHANNEL B
VINA OR VINB = 5V
50
-25
0
25
50
75
100
0.16
0.14
0.12
0.10
0.08
0.06
0.04
70
60
50
0
0.80
0.60
0.40
25
50
75
100
125
-50
2.5
1.2
1.5
IN (V)
April 24, 2015
4.5
5.0
75
100
125
VIN = 3.3V
RILIM = 10kΩ
0.8
0.6
1
0.4
0.2
0
4.0
50
1.0
0.5
3.5
25
2
VILIM (V)
CURRENT LIMIT (A)
1.4
0.4
0
VILIM
vs. Load Current
1.4
3.0
-25
TEMPERATURE (°C)
3
0.6
5.0
1.00
1.6
0.8
4.5
1.20
Current Limit
vs. ILIM Resistance
EN On Voltage
vs. IN Voltage
1
4.0
1.40
TEMPERATURE (°C)
1.2
3.5
0.00
-25
TEMPERATURE (°C)
2.5
3.0
0.20
-50
125
80
1.60
0.00
-50
90
Output to VINA or VINB Leakage
vs. Temperature
0.02
40
100
INA OR INB (V)
LEAKAGE CURRENT (µA)
LEAKAGE CURRENT (µA)
70
110
2.5
0.18
80
120
125
0.20
90
130
40
-50
100
SWITCH-ON RESISTANCE (mΩ)
SWITCH ON-RESISTANCE (mΩ)
250
ISUPPLY (µA)
ISUPPLY (µA)
140
INA OR INB SELECTED
INA OR INB
SELECTED
250
EN ON VOLTAGE (V)
Switch On-Resistance
vs. INA or INB
0.0
0
2
4
6
ILIM RESISTANCE (kΩ)
6
8
10
0
50
100
150
200
250
300
LOAD CURRENT (mA)
Revision 1.0
Micrel, Inc.
MIC1344
Typical Characteristics (Continued)
1.4
3
3
VIN = 3.3V
RILIM = 1kΩ
RILIM = 931Ω
2.5
1.0
0.8
0.6
0.4
CURRENT LIMIT (A)
2.5
CURRENT LIMIT (A)
1.2
VILIM (V)
Current Limit
vs. IN
Current Limit
vs. Temperature
VILIM
vs. Load Current
2
1.5
1
RILIM = 10kΩ
0.5
0.2
0.0
0.5
1.0
1.5
2.0
2.5
3.0
1.5
1
RILIM = 10kΩ
0
-50
-25
0
25
50
75
TEMPERATURE (°C)
LOAD CURRENT (A)
2
0.5
0
0.0
RILIM = 931Ω
100
125
2.5
3.0
3.5
4.0
4.5
5.0
IN (V)
Output Switchover Voltage
Droop vs. Load Capacitance
OUTPUT VOLTAGE DROOP (V)
4.5
AUTOMATIC MODE
VINA = 4.5V
VINB = 4V to 5.5V
RL = 10 Ω
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
0.1
1.0
10.0
100.0
CL LOAD CAPACITANCE (µF)
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MIC1344
Functional Characteristics
April 24, 2015
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MIC1344
System Connection Diagram
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MIC1344
Functional Block Diagram
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MIC1344
Application Information
Operation Overview
The MIC1344 is an advanced two input, one output, hot
swappable, power multiplexer. It has both automatic and
manual input selection (ENA and ENB), and four status
outputs (STAOK, STBOK, ASEL\, and BSEL\). The
following sections give a more detailed explanation
regarding the application of this part.
When no input is selected, the MIC1344 will block current
flow from the output (OUT), to either input (INA or INB),
as well as from either input (INA or INB) to the output
(OUT).
For applications that require changing between the A and
B power input with only one control line, set ENA = 1, and
use the ENB input to set which of the two inputs is active.
Channel Selection
Table 1 shows how the MIC1344 will route the input
power as controlled by the ENA and ENB input pins. If a
transition occurs on either ENA or ENB, the part will wait
an additional 10µs before implementing the new code.
This delay allows the two enable pins to be slightly out of
sync and not cause a momentary selection of an
unwanted mode.
Current Limiting
The current limits in the two inputs of the MIC1344 can
be set independently. This allows mixing input sources
that have different current capacity, like a main, and
backup power supply. The current limit for INA is set by
the ILIMA resistor to GND, while the current limit for INB
is set by the ILIMB resistor to GND. A graph of the ILIM
resistance vs current limit can be found in the Typical
Characteristics section of this datasheet.
Table 1. ENA and ENB Input Power Selection
ENA
ENB
Power Input Selected
0
0
Automatic mode. The higher voltage on
either INA or INB automatically selected if >
VUVLO.
0
1
No input selected (can be used for
cascading other MIC1344 power inputs).
1
0
INA power input selected if VINA > VUVLO.
1
1
INB power input selected if VINB > VUVLO.
The ILIM resistor value can be calculated by Equation 1:
R ILIM =
Eq. 1
Where:
ICL = Desired current limit (A)
If the values of ENA and ENB are logic low when the
MIC1344 powers up, the MIC1344 will automatically
select the power input with the higher voltage and route it
to the output. This is the normal power-up sequence for
the MIC1344. If both inputs are below the undervoltage
lockout voltage, then the output will be high impedance. If
the select inputs are driven by external logic that is
powered by the MIC1344, then those logic outputs can
either be low or open circuit, and the MIC1344 will
automatically bias up the logic when it is powered up.
RILIM = Resistor value for ILIM pin (Ω)
RILIM should be set between 11kΩ and 800Ω. Setting
resistor RILIM equal to zero is not recommended as it will
disable current limiting.
During a current limit event, if the MIC1344 is in
automatic mode, then the automatic switching will be
blocked because switching over to the other channel will
load it, taking its voltage low, and unloading the other
channel taking its voltage high. Blocking the automatic
switchover mode prevents the possible oscillation of the
MIC1344 switching between the two inputs, as they
become loaded by the heavy load condition. Switching
the channels manually is allowed.
Both input power sources can be turned off by putting
ENA = 0, ENB = 1 on the enable input pins. One
operating scenario to be aware of is that if the Logic 1 on
the ENB input is generated by a device powered via the
MIC1344 output, the input of the MIC1344 will be set at
ENA = 0 and ENB = 0 when the power is turned off. With
ENA = 0 and ENB = 0, the part will automatically select
the higher of the two input voltages and turn back on
again. The no input selected mode is typically used when
more than two power sources are required (cascading
multiple MIC1344s) and both inputs must be turned off so
that the third or fourth power input can be turned on.
April 24, 2015
2485
ICL − 146µA
Current flowing in the INA or INB inputs can be measured
by the voltage on the corresponding ILIM pin. These pins
can be connected to the input of an analog-to-digital
converter (ADC), to read the current digitally. When the
voltage at the ILIM pins reaches 1.20V (typical), the
MIC1344 will regulate the input current on the
corresponding input to the maximum value and make the
corresponding status pin (STAOK or STBOK) go active
(low). The MIC1344 will hold this maximum value
indefinitely or until the part overheats. Should the part
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MIC1344
overheat, it will turn off both input channels and both
status pins (STAOK and STBOK) will go active (low).
The voltage on the ILIM pin can be calculated by
Equation 2:
VILIM =
(IOUT × RILIM × 82.1Ω)
(RILIM + 170kΩ)
Eq. 2
Where:
IOUT = Current out of the OUT pin (A)
RILIM = Resistor value attached to the ILIM pin (Ω)
Figure 1. STAOK Correctly Flags for Low Input Voltage
when STAOK’s Pull-Up Resistor is connected to INA
The current limit circuit is filtered to avoid erroneous
flagging of the STAOK or STBOK pins from output
current spikes. The current limit must be engaged for at
least greater than 50% of the time over a prolonged
period of time, or constantly for at least ≈5ms before the
flag is driven low. The flag will then be held low for at
least ≈5ms after the current limit event is over, or until the
current limit is engaged less than 50% of the time over a
prolonged period of time.
If the pull-up is connected to another voltage and INA is
below the NMOS threshold, then the STAOK can falsely
indicate that the input voltage is acceptable. This occurs
due to the INA monitoring circuit requiring enough voltage
to turn on the STAOK open-drain output transistor.
This is also true for the INB and corresponding STBOK
status indicator and the ASEL\ and BSEL\ outputs (see
Figure 2).
If the MIC1344 changes between input channels that
have different current limits, the load may need to be
changed to accommodate the different current limit value.
If there is a system controller, it would be notified of the
selected INA or INB input channel through the ASEL\ and
BSEL\ outputs. One example is a situation where a
microprocessor runs two different programs or load sets,
depending on whether the power is main (normal input
power), or backup (battery, etc.).
Digital Status Output Pins
The MIC1344 features four digital channel status output
pins, specifically STAOK, ASEL\, STBOK, and BSEL\.
The power for the status pins is acquired from the
corresponding input, i.e., the control power for STAOK
and ASEL\ is acquired from INA with INB providing the
control power for STBOK and BSEL\. The digital status
pins are open drain and require pull-up resistors to
function. It is recommended that the open-drain pull-up
resistors be connected to the corresponding input power
to ensure the indicators will be accurate below the UVLO
voltage. STAOK and ASEL\ should be pulled-up to INA
with STBOK and BSEL\ being pulled-up to INB. If there is
no voltage at INA, the STAOK output will be high
impedance. If the pull-up resistor on STAOK is connected
to VINA, then the STAOK will indicate the status of the
input voltage correctly (see Figure 1).
April 24, 2015
Figure 2. STAOK Incorrectly Flags for Low Input Voltage
when STAOK’s Pull-Up Resistors is connected to
External 5V Supply
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MIC1344
The ASEL\ and BSEL\ status pins indicate which channel
is selected and connected to the output. If ASEL\ is active
(low), then INA is selected and if BSEL\ is active (low),
then INB is selected. If both ASEL\ and BSEL\ are
inactive (open-drain high), then neither of the two inputs
is selected. This can occur if both INA and INB input
voltages are below the undervoltage lock out (UVLO)
voltage, or both inputs have been manually turned-off
(ENA = 0, ENB = 1).
Hot Swappable Inputs
The power to INA and/or INB can be connected to input
power and turned on or off without consequence to the
other input power supply, as long as the minimum and
maximum input voltage does not exceed the ratings of
the MIC1344. If the MIC1344 is set to automatic mode
(ENA = 0, ENB = 0), and power is applied to one of the
channels, the MIC1344 will wait until the input voltage is
above the UVLO threshold, then it will wait the initial
power up delay period, giving time for the input voltage to
stabilize, and then connect the selected input to the OUT
pin. Refer to the “Current Limiting” sub-section for details
of what occurs if the INA or INB input channels current
limit.
If high-value pull-up resistors are used (>100kΩ), then
minimal current will be injected into the digital input pins,
allowing them to stay at a digital low for a lower input
voltage below the UVLO voltage.
Each digital status output pin is capable of sinking 10mA,
which is sufficient current to drive LEDs, optocouplers,
etc. Passing the status of the MIC1344 through
optocouplers allows communicating the power status
across the isolation barrier of power systems.
Cascading More than Two Input Power Sources
On the MIC1344, both inputs can be turned off using the
ENA = 0, ENB = 1, no input selected mode. This mode is
used when more than two power inputs are used. If there
is an input voltage at either INA or INB, the
corresponding digital output status pins will stay active.
This allows detection of the presence of an input voltage
through the corresponding STAOK or STBOK pins, even
if the channel is not selected.
Under Voltage Lockout
Both INA and INB have separate UVLO detection circuits.
The UVLO status of INA is reflected on the STAOK status
pin. Likewise, the UVLO status of INB is reflected on the
STBOK status pin. This feature can be used to monitor
the incoming voltage of the unselected input channel. If
the selected IN pin is below the UVLO voltage, then the
channel will be turned off, and only reverse leakage
current can flow.
Reverse Voltage and On-Channel Voltage Detection
If one of the channels of the MIC1344 is turned off,
current is blocked from flowing from the OUT pin to the
unselected IN pin. For example; If INA is at 5V, and INA
is selected, only a very small leakage current (<10µA
maximum) will flow between OUT, and the unselected
INB.
Standard Hysteresis Mode
In automatic mode, the voltage of the inactive input must
be raised above the voltage of the active input by
≈300mV, in order for the MIC1344 to switch to the
inactive input.
If a channel is turned on and the OUT voltage exceeds
the corresponding IN voltage, then reverse current may
flow to the input. If the voltage at the OUT pin exceeds
the voltage at the correspondingly selected IN pin, then
the channel will be turned off and the corresponding
STAOK or STBOK pin will go active (low). For example, if
INA is selected and OUT exceeds INA by ≥ 100mV, then
Channel A will be turned off and STAOK will go active,
indicating that a fault has occurred. The same sequence
occurs if Channel B is selected and OUT exceeds INB by
≥100mV. Once the differential between OUT and the
selected IN drops to ≈50mV, the selected channel will
automatically turn back on.
High Hysteresis Mode
If four transitions between input channels occur within
≈8ms (INA → INB → INA → INB) while the part is in
automatic mode, then the 300mV switchover hysteresis
will increase to ≈600mV. This is the high hysteresis
mode. In the high hysteresis mode the part can only
switch between channels once per millisecond. The
higher hysteresis and the forced delay helps prevent the
part from chattering between inputs.
In the high hysteresis mode, if there are four additional
transitions in the next ≈8ms, then the status pin for the
selected channel will go low (STAOK if VINA selected
and STBOK if VINB is selected).
Output Capacitor
The output (OUT) requires sufficient capacitance that
when the MIC1344 switches between inputs (INA or INB),
that the output voltage does not unacceptably droop (go
low). The cause of the output voltage drooping is that the
MIC1344 switches “break before make”, which will
momentarily disconnect both inputs from the output. The
switchover delay is specified in the Electrical
Characteristics. A minimum of a 10µF ceramic chip
capacitor is recommended on the output of the MIC1344.
The part will exit the high hysteresis mode if there are
fewer than four transitions in a subsequent ≈8ms period,
or if a manual mode is selected.
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MIC1344
Overtemperature Shutdown
There is one die temperature monitor for both channels of
the MIC1344. If one of the two input channels causes an
overtemperature condition, both channels will be shut
down, and both the STAOK, STBOK outputs will be
active (low impedance, logic low), indicating that a fault
has occurred. If the overtemperature condition is created
by one of the INA or INB channels being in an
overcurrent condition, then this condition can be
determined by reading the voltage on the ILIMA or ILIMB
pins after the part cools down and the output recovers.
PCB Layout Recommendations
The MIC1344 comes in an ultra-small small 2mm × 2mm
package. The part has to have sufficient PCB area,
and/or air flow so that it will not overheat. Given a 3A load
current, a nominal on-channel resistance of 70mΩ, a
junction to ambient thermal resistance of 77.9°C/W
(depends on PCB area and air flow), and an ambient
temperature of 76°C, the MIC1344 die temperature will
operate at the 125°C limit. The MIC1344 Evaluation Kit
manual has more specifics on a recommended PCB
layout for the MIC1344.
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MIC1344
Package Information and Recommended Landing Pattern(14)
12-Pin 2mm × 2mm FTQFN (FT)
Note:
14. Package information is correct as of the publication date. For updates and most current information, go to www.micrel.com.
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MIC1344
Package Information and Recommended Landing Pattern(14) (Continued)
12-Pin 2mm × 2mm FTQFN (FT)
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MIC1344
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
Micrel, Inc. is a leading global manufacturer of IC solutions for the worldwide high performance linear and power, LAN, and timing & communications
markets. The Company’s products include advanced mixed-signal, analog & power semiconductors; high-performance communication, clock
management, MEMs-based clock oscillators & crystal-less clock generators, Ethernet switches, and physical layer transceiver ICs. Company
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Micrel makes no representations or warranties with respect to the accuracy or completeness of the information furnished in this datasheet. This
information is not intended as a warranty and Micrel does not assume responsibility for its use. Micrel reserves the right to change circuitry,
specifications and descriptions at any time without notice. No license, whether express, implied, arising by estoppel or otherwise, to any intellectual
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whatsoever, and Micrel disclaims any express or implied warranty relating to the sale and/or use of Micrel products including liability or warranties
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Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product
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