MICREL MIC2310-1ZTS

MIC2310
Single-FET, Constant Power-Limit Hot
Swap Controller
General Description
Features
The MIC2310 is a single-channel, positive voltage,
constant power-limit hot swap controller designed to
provide for the safe insertion and removal of pc boards into
fixed, rack, and pedestal mid- or back-planes using few
external components. In addition, the MIC2310 employs a
patent-pending, output load power-limiting technique
where the current limit is inversely proportional to the
output load voltage, such that the power product will not
exceed the programmed power limit any longer than the
externally programmed primary overcurrent period. The
MIC2310 is ideally suited to address the power-limiting
and timing requirements per the UL60950 specification for
240-VA applications. The MIC2310 incorporates high-side
controller circuitry for an external N-channel MOSFET for
which the MOSFET drain current rate of change is userprogrammable via an external capacitor. The MIC2310
employs dual-speed, dual-level overcurrent fault
protection. The primary overcurrent detector response time
is programmable via an external current sense resistor and
the secondary overcurrent detector is 2-bit userprogrammable and exhibits a very fast (default) response
to faults to ensure that the system power supplies are
protected against catastrophic load current and shortcircuit faults. Additionally, an analog output (voltage) signal
is provided that is proportional to the steady-state load
current to allow monitoring of the system’s power. A
PWRGD signal is provided to indicate a valid output
voltage that can be used to enable a DC-DC power
module.
Data sheets and support documentation can be found on
Micrel’s web site at www.micrel.com.
•
•
•
•
•
•
•
•
Provides safe PCB insertion and removal from live
+12V backplanes
Patent-pending, adaptive circuit breaker threshold
control
– Maintains constant power product at output
– Power-limit product (VA) is externally
programmable for various power applications
Dual-level, dual-speed overcurrent detection/protection
– Programmable primary detector response time
– Fast (< 1 µs) secondary detector response time to
short circuit conditions
ƒ User-programmable threshold settings via (2)
digital inputs
Steady-state load current monitoring
Programmable inrush current slew-rate control
Electronic circuit breaker functions after fault
– Latch off
– Automatic retry
Programmable input undervoltage lockout and
overvoltage protection
Fault reporting:
– Open-drain ‘Power-is-Good’ output
– Open-drain ‘I_FLT’ output signaling for all current
faults
– Shorted RSENSE and Damaged MOSFET detection
(D-G and D-S shorts)
Applications
•
•
•
•
•
•
•
UL60950, EN60950, and CSA1950 systems (240-VA)
General Power-limiting Applications
Base stations
Enterprise servers
High-reliability servers
Enterprise switch networks
+12V backplanes
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
July 2008
M9999-070108-A
Micrel, Inc.
MIC2310
Typical Application
RSENSE
VIN
12V
1
C2*
0.5%
3
Q1
IRL3713S
D2Pak
2
4
R1
R2
C3
0.68µF
R3
C1
1.5µF
1%
VOUT
12V@20A
24
VCC
6
ENABLE
1
UVLO
R4
1%
R5
2
1%
7
23
VCCSENSE
22
SENSE
C4
0.47µF
11
CSLEW
10
C7
0.01µF
21
CPRIMARY
19
GATE
SOURCE
LOADSENSE
GNDSENSE
17
DISCH
16
VREG
4
3
OVP
MIC2310
S0
CDISCH
Q2
ZUMT618
SOT-323
C6
0.1µF
S1
VISS
TO SYSTEM
MANAGEMENT
CONTROLLER
R9
CLOAD
S[1,0]=X,X
8
18
CRETRY
3
9
CPGND
AGND
20
HW_FLT
12
13
PWRGD
14
C5
0.068µF
I_FLT
15
R8
V LOGIC
R7
R6
Overcurrent
Fault Output
* The value of C2 is flexible and dependant upon the
parasitic inductance, which should be minimzed as much
as possible. A
inductance) for C2 is 56µF, minimum
July 2008
Power-Good
Output
Hardware
Fault Output
2
M9999-070108-A
Micrel, Inc.
MIC2310
Ordering Information
Part Number
PWRGD State
I_FLT State
Fault Condition Status
Package
Lead Finish
MIC2310-1ZTS
Active-HIGH
Active-HIGH
Latched/Auto-retry
24-pin TSSOP
Pb-Free
MIC2310-2ZTS
Active-LOW
Active-LOW
Latched/Auto-retry
24-pin TSSOP
Pb-Free
Note:
1. Other Voltage available. Contact Micrel for details.
Pin Configuration
UVLO
1
24 VCC
UVLO
1
24 VCC
OVP
2
23 VCCSENSE
OVP
2
23 VCCSENSE
VISS
3
22 SENSE
VISS
3
22 SENSE
VREG
4
21 GATE
VREG
4
21 GATE
NC
5
20 CPGND
NC
5
20 CPGND
ENABLE
6
19 SOURCE
ENABLE
6
19 SOURCE
S0
7
18 LOADSENSE
S0
7
18 LOADSENSE
S1
8
17 GNDSENSE
S1
8
17 GNDSENSE
CRETRY
9
16 DISCH
CRETRY
9
16 DISCH
CPRIMARY 10
15 /I_FLT
CPRIMARY 10
15 I_FLT
CSLEW 11
14 PWRGD
CSLEW 11
14 /PWRGD
AGND 12
13 HW_FLT
AGND 12
13 HW_FLT
24-pin TSSOP (TS)
MIC2310-1ZTS
July 2008
24-pin TSSOP (TS)
MIC2310-2ZTS
3
M9999-070108-A
Micrel, Inc.
MIC2310
Pin Description
Pin Number
Pin Name
1
UVLO
Undervoltage Lockout Input. When the applied voltage at the UVLO pin is higher
than the controller’s VUVLOH threshold voltage, the GATE drive circuits are active
when ENABLE= HIGH. If the applied voltage at the UVLO pin falls below the
controller’s VUVLOL threshold voltage, the GATE drive circuits are disabled to turn
the external MOSFET OFF. In addition, the DISCH circuit is activated to drive an
optional, external discharge transistor alone (illustrated in the Typical Application
circuit) or in combination with an SCR for a very fast discharge circuit
configuration.
2
OVP
Overvoltage Protection Input. When the applied voltage at the OVP pin is higher
than the controller’s VOVPH threshold voltage, the GATE drive circuit is disabled
to turn the external MOSFET OFF. In addition, the DISCH circuit is activated to
drive an optional, external discharge transistor alone (illustrated in the Typical
Application circuit) or in combination with an SCR for a very fast discharge circuit
configuration. Using an external resistor divider, the UVLO and the OVP pins
form a window comparator that defines the supply voltage range within which the
load may be safely powered.
3
VISS
Steady-state Output Current Monitor. This output signal provides an analog
voltage that is proportional to the steady-state load current. This signal is
provided as an input to the system supervisor/processor to monitor the dc
current/power level of the application circuit.
4
VREG
Internal +5V Regulator Bypass. Connect a 0.1-µF, 16V ceramic capacitor from
this pin to AGND.
5
NC
6
ENABLE
ENABLE Input. An active asserted-HIGH digital input that controls the operation
of the MIC2310. Activated after the internal POR timer has terminated, a LOWto-HIGH transition on this pin commences a start-up sequence if the applied VCC
is above the VUVLOH and below the VOVPH threshold voltages. While ENABLE =
LOW, the GATE pin is held to 0V and the DISCH output is activated. The
ENABLE input can be used to reset the internal circuit breaker by applying a
HIGH-to-LOW-to-HIGH transition as defined by tENLPW following either a load
current fault, an open LOADSENSE fault, an open GNDSENSE fault, or a
shorted RSENSE fault.
7
S0
8
S1
Secondary OC Detector Current Threshold Digital Inputs – S1 is the MSB and
S0 is the LSB. When used together, S[1:0] sets the overcurrent threshold for the
secondary overcurrent detection circuit to one of four levels relative to the
primary overcurrent detector nominal threshold. For example, S[1:0] = L, L sets
the secondary overcurrent threshold at 1.3X; S[1:0] = L, H sets a 1.5X threshold;
S[1:0] = H, L sets a 2X threshold, and S[1:0] = H, H sets a 1.75X threshold. If the
S[1:0] pins are not connected or left NC, the default setting is S[1:0] = L, L or
1.3X. The permissible voltage range on these inputs is AGND ≤ S[1:0] ≤ VCC.
9
CRETRY
Auto-retry Timing Capacitor. A capacitor connected from the CRETRY pin to
AGND configures the MIC2310 to re-start automatically with ENABLE = HIGH
after the circuit breaker trips and latches off. It also sets the “cool-off” time delay
before a new load current start-up sequence is initiated. To configure the
MIC2310’s circuit breaker to latch off after fault, connect this pin to AGND. The
circuit breaker latches OFF and remains latched OFF unless the ENABLE input
is toggled HIGH-to-LOW-to-HIGH as defined by tENLPW or the VCC supply voltage
is turned OFF then ON.
10
CPRIMARY
Primary Overcurrent Detector Timing Capacitor. Connecting a capacitor from the
CPRIMARY pin to AGND sets the response time of the controller’s primary
overcurrent detection circuit to GATE OFF in the event of an overcurrent
condition. If the CPRIMARY pin is not connected, the primary overcurrent
detection response time defaults to tPOCSENSE, typically 250µs as specified in the
Electrical Characteristics Table. The controller incorporates a patent-pending
built-in test for a faulty CPRIMARY capacitor.
July 2008
Pin Function
No connection
4
M9999-070108-A
Micrel, Inc.
MIC2310
Pin Description (continued)
Pin Number
Pin Name
11
CSLEW
12
AGND
13
HW_FLT
Pin Function
Inrush Current Slew Rate Control Input. To adjust the inrush load current profile
(controlled dIDRAIN/dt), connect a capacitor from this pin to VCC. To adjust the
MOSFET GATE voltage profile (controlled dVGATE/dt), leave this pin OPEN
(floating) and connect a capacitor from GATE to AGND. For additional
information on the operation of this function, please refer to the Functional
Description section.
Analog Ground. Connect this pin to the system analog ground plane.
External MOSFET Hardware Fault Digital Output. This output is an open-drain,
active-HIGH signal that should be connected to a +3.3V logic supply by a 10kΩ
resistor. This digital output is active after the internal POR timer has terminated
and becomes asserted (HIGH) due to a fault under the following conditions: a) a
shorted DG MOSFET with ENABLE = LOW; b) a shorted DS MOSFET with
ENABLE = LOW; c) a shorted RSENSE; d) a shorted DS MOSFET after steadystate operation with ENABLE = HIGH-to-LOW; or e) a shorted DG or DS while
EN = HIGH and DISCH = HIGH; or f) a shorted CPRIMARY to AGND. The
HW_FLT output is latched and is reset when VCC is brought low such that
VREG < VVREG(UVLO).
14
PWRGD
/PWRGD
15
I_FLT
/I_FLT
July 2008
Power Good Digital Output. This output is an open-drain, active-HIGH (PWRGD)
or active-LOW (/PWRGD) signal that should be connected to a +3.3-V logic
supply by a 10kΩ resistor. This digital output is active after the internal POR
timer has terminated and becomes asserted when the voltage between the
LOADSENSE and the GNDSENSE pins is higher than the controller’s VPGH
threshold voltage. It is de-asserted when the voltage between the LOADSENSE
and the GNDSENSE pins is less than the controller’s VPGL threshold voltage.
Load Current Fault Digital Output. This output is an open-drain, active-HIGH
(I_FLT) or active-LOW (/I_FLT) signal that should be connected to a +3.3V logic
supply by a 10kΩ resistor. This digital output is active after the internal POR
timer has terminated and becomes asserted whenever the primary or secondary
overcurrent detection circuits cause the internal circuit breaker to latch OFF. The
digital output remains asserted unless the ENABLE input is toggled HIGH-toLOW-to-HIGH as defined by tENLPW or the VCC supply voltage is turned OFF then
ON or if the auto-retry mode is enabled.
Discharge External Transistor Drive Output. When ENABLE = LOW or after a
fault condition (either an overcurrent fault or hardware fault such as a shorted
MOSFET) that causes either the primary and secondary overcurrent detectors to
trip the internal circuit breaker, the DISCH circuit is activated to provide gate
drive to optional, external transistors (and SCR, for very fast load discharge).
These transistors serve as auxiliary gate pull-down or load voltage pull-down
switches. A load voltage pull-down is illustrated in the Typical Application circuit.
16
DISCH
17
GNDSENSE
18
LOADSENSE
19
SOURCE
External Power MOSFET Source Pin Monitor. To protect external circuits
downstream of the controller, internal monitor circuits are included to sense a
shorted drain-source condition of the external power MOSFETs.
20
CPGND
Internal charge pump power ground. Connect this pin directly to the system’s
analog ground plane.
21
GATE
These input pins (when used together) sense the load voltage and provide
feedback to the controller’s adaptive VA limit and Power-Good circuits. The
voltage across these two pins also sets the controller’s Power-Is-Good status
output as defined by the specified VPGH or the VPGL threshold voltages. Internal
circuit monitors are included if either or both LOADSENSE and GNDSENSE
connections are severed or not connected to the load.
External N-channel MOSFET GATE Drive Output. The GATE output signal uses
an internal charge pump to charge the gate of an external N-channel MOSFET
pass transistor.
5
M9999-070108-A
Micrel, Inc.
MIC2310
Pin Description (continued)
Pin Number
July 2008
Pin Name
22
SENSE
23
VCCSENSE
24
VCC
Pin Function
By connecting a very low value (mΩ) current sense resistor between these two
pins, the MIC2310’s internal primary and secondary overcurrent detection
circuits monitor the load current. The VCCSENSE pin is the positive (+) input
terminal and the SENSE pin is the negative (-) input terminal of the overcurrent
detection circuits. If the voltage across the sense resistor exceeds either the
primary overcurrent threshold for a time (tPOC) or the secondary primary
overcurrent threshold for any duration, the MIC2310 electronic circuit breaker is
tripped, the GATE is turned OFF, the DISCH circuit is activated, and the I_FLT
digital output is asserted. The controller also incorporates a patent-pending builtin test for shorted current-sense resistors. Because of this built-in self test, the
MIC2310’s electronic circuit breaker cannot be disabled by connecting together
the VCCSENSE and SENSE pins.
Positive supply input to the MIC2310. The MIC2310 is specified to operate from
+10.8V ≤ VCC ≤ +13.2V and the supply current with ENABLE = HIGH is less than
10mA.
6
M9999-070108-A
Micrel, Inc.
MIC2310
Absolute Maximum Ratings(1)
Operating Ratings(2)
VCC, VCCSENSE, SENSE, LOADSENSE, ENABLE,
CSLEW, S1, S0, SOURCE..................... –0.3V to +18V
GATE............................................................. –0.3V to +30V
UVLO, OVP, VISS, CRETRY, CPRIMARY, HW_FLT,
PWRGD, I_FLT, DISCH, GNDSENSE .... –0.3V to +6V
Output Current
HW_FLT, PWRGD, I_FLT pins ...................................10mA
ESD Rating (All pins)
Human Body Model .............................................. 2kV(3)
Machine Model ......................................................200V
Lead Temperature (Soldering) Pb-free package
IR Reflow ..........................................+260°C +0°C/-5°C
Storage Temperature..........................–65°C to +150°C
Supply Voltage (VCC)................................ +10.8V to +13.2V
Ambient Temperature Range (TA) ................ 0 °C to +70 °C
Junction Temperature (TJ) ...................................... +125 °C
Package Thermal Resistance (θJA)
24-pin TSSOP................................................83.8 °C/W
DC Electrical Characteristics(4)
VCC = +12V, CREG = 0.1µF, TA = +25 ºC unless otherwise noted. Bold indicates specification applies over the full
operating temperature range of 0 ºC to +70 ºC. All voltages are measured with respect to AGND unless otherwise
noted.
Symbol
Parameter
VCC
Operating Supply Voltage
(Constant Output Power)
Supply Current
Internal VREG Undervoltage
Lockout High Threshold
Voltage
Internal VREG Undervoltage
Lockout Low Threshold
Voltage
UVLO High Threshold
Voltage
UVLO Low Threshold
Voltage
UVLO Pin Input Current
OVP High Threshold Voltage
OVP Low Threshold Voltage
OVP Pin Input Current
“Power-is-Good” GATESOURCE Threshold
“Power-is-Good” High
Threshold
(VLOADSENSE – VGNDSENSE)
ICC
VVREG(UVLOH)
VVREG(UVLOL)
VUVLOH
VUVLOL
IUVLO
VOVPH
VOVPL
IOVP
VGSPGH
VPGH
VPGL
VREG
July 2008
“Power-not-Good” Low
Threshold
(VLOADSENSE – VGNDSENSE)
VREG Output Voltage
Condition
Min
ENABLE = LOW,HIGH
VREG Low-to-High Transition
Typ
Max
Units
10.8
13.2
V
3.95
10
4.5
mA
V
4.25
V
4.25
3.70
Low-to-High Transition
0.96
1.00
1.04
V
High-to-Low Transition
0.91
0.941
0.97
V
1.35
1.295
1.407
1.339
5
1.45
1.395
5
4.25
5
µA
V
V
µA
V
9.3
9.7
10.1
V
8.4
9
9.6
V
4.5
5
5.5
V
UVLO = 6V
Low-to-High Transition
High-to-Low Transition
OVP = 6V
(VGATE – VSOURCE)
Low-to-High Transition,
(VGATE – VSOURCE) ≥ VGSPGH
Measured with respect to
GNDSENSE = AGND
High-to-Low Transition,
(VGATE – VSOURCE) ≥ VGSPGH Measured
with respect to GNDSENSE = AGND
RREG > 1 MΩ
7
M9999-070108-A
Micrel, Inc.
MIC2310
Symbol
Parameter
Condition
Min
Typ
Max
Units
VCBP
Primary OC Circuit Breaker
Threshold Voltage
VVCCSENSE – VSENSE
VCBS
Secondary OC SENSE
Voltage
VVCCSENSE - VSENSE
54.7
60.7
49.6
64
75
100
85
57.2
63.5
51.9
75.5
87.5
116.6
102
59.7
66.3
54.2
87
99
130
116
mV
mV
mV
mV
mV
mV
mV
IVCCSENSE
VCCSENSE Pin Input
Current
SENSE Pin Input Current
CRETRY Pin High
Threshold Voltage
CRETRY Pin Low Threshold
Voltage
CRETRY Pin Charging
Current
CRETRY Pin Pull-down
Current
CPRIMARY Pin Low
Threshold Voltage
(VLOADSENSE – VGNDSENSE) = +12V
(VLOADSENSE – VGNDSENSE) = +10.8V
(VLOADSENSE – VGNDSENSE) = +13.2V
S[1:0] = L, L
Secondary OC
Detector Circuit S[1:0] = L, H
Breaker Trips,
S[1:0] = H, L
VLOADSENSE –
S[1:0] = H,H
VGNDSENSE =
10.8V to 13.2V
VVCCSENSE = VCC
1
µA
µA
V
ISENSE
VRETRYH
VRETRYL
IRETRYUP
IRETRYDN
VPRIL
VPRIL
CPRIMARY Pin Low
Threshold Voltage
IPRI
CPRIMARY Pin Charging
Current
VSENSE = VCC
TIMER ON,
VRETRY = 0V
TIMER OFF,
VRETRY = 1.5V
During OC response;
ENABLE = HIGH;
VCC(SENSE) – VSENSE > VCBP
Measured relative to VREG
During shorted
ENABLE = HIGH;
CPRIMARY
VCC(SENSE) – VSENSE
detection;
< VCBP
Measured
ENABLE
= LOW
relative to V
1.21
1.25
3
1.28
0.25
0.3
0.35
V
-4.25
-3
-1.65
µA
3
mA
-1.3
-1.25
-1.2
V
-1.3
-1.25
-1.2
V
2.4
3
3.6
µA
-4.5
-3
-1.5
mA
-4.5
-3
-1.5
mA
15
V
REG
∆VGATE
GATE Output Voltage
∆VCP
ISLEW
VCSLEW – VSENSE Differential
July 2008
Inrush Current slew
Charging current
During Primary OC Fault
VCPRIMARY = VREG;
ENABLE = HIGH
VCC(SENSE) – VSENSE > VCBP
During nominal and reset operation
VPRIMARY = VREG – 1.25V;
ENABLE = HIGH
VCC(SENSE) – VSENSE < VCBP
During disable;
VCPRIMARY = VREG – 1.25V
ENABLE = LOW
(VGATE-VCC): VCC > 10.5V
Internally clamped
Charge pump to OFF
VCSLEW = VCC – 50mV
8
8
50
5
10
mV
15
µA
M9999-070108-A
Micrel, Inc.
MIC2310
Symbol
Parameter
Condition
Min
Typ
Max
Units
IGATEUP
GATE Pin Pull-up Current
-60
-30
-15
µA
IGATEDN
Normal GATE Pin Pull-down
Current
Charge pump ON,
VGATE = VSOURCE = +13.2V
ENABLE = LOW,
VGATE = 2V
I_FLT Latched and OC Detector Trip
or in UVLO, VGATE = 2V
1.0
2.7
4.5
mA
45
120
mA
5
V
5
V
VSOURCE - VLOADSENSE
4
V
VGNDSENSE
4
V
VGATEFT(EXT)
VSRCFT(EXT)
VTHLOADSENSE
VTHGNDSENSE
ISOURCE
Fault-mode GATE Pin Pulldown current
GATE-to-AGND Fault
Threshold
ENABLE = LOW
SOURCE-to-AGND Fault
Threshold
ENABLE = LOW
Open LOADSENSE
Threshold
Open GNDSENSE
Threshold
SOURCE Pin Input Current
ILOADSENSE
LOADSENSE Pin Input
Current
IGNDSENSE
GNDSENSE Pin Input
Current
Shorted RSENSE Threshold
Voltage at SOURCE
(VSENSE – VSOURCE)
Shorted RSENSE Threshold
Voltage
(VVCCSENSE – VSENSE)
DISCH Pin Drive Voltage
DISCH Pin Drive Current
Linear Sensing Range
Zero Voltage VISS Output
Voltage
VISS DC Output Resistance
∆VDS(FET)
∆VRSENSE
VDISCH
IDISCH
VISS(LIN)
VISS(Q)
RVISS
VISS(SENS)
ETOT
July 2008
VISS Analog Signal
Sensitivity
VISS Total Error % (240 VA)
EN = LOW, 0V ≤ SOURCE ≤ VCC
EN = HIGH, SOURCE = VCC
EN = HIGH, /FAULT Condition
0V ≤ SOURCE ≤ VCC
+10.8V ≤ VLOADSENSE ≤ +13.2V
VLOADSENSE = 0V
DISCH = HIGH
VGNDSENSE = 0V
18
1.5
18
µA
µA
µA
300
300
µA
µA
µA
-400
VCC(SENSE) – VSENSE = 0V,
VGATE – VSOURCE > VGSPGH
7
mV
VSENSE – VSOURCE = 30mV,
VGATE – VSOURCE > VGSPGH
12
mV
IDISCH = 12mA
VDISCH = 2.5V
VVCC(SENSE) - VSENSE
VVCC(SENSE) - VSENSE = 0mV
0
7
VVCC(SENSE) - VSENSE = 60mV
9
V
µA
mV
mV
32
kΩ
V/V
±10
%
100
[VISS(20µA) -VISS(10µA) ]/10µA
∆VVISS/∆( VVCC(SENSE) - VSENSE)
55
0.4
-400
90
103
28
30
M9999-070108-A
Micrel, Inc.
MIC2310
Symbol
Parameter
Condition
ELIN
VISS Analog Nonlinearity
VVCC(SENSE) - VSENSE = 0mV to 90mV
VOL
LOW-Level Output Voltage
I_FLT, PWRGD, HW_FLT
LOW-Level Input Voltage
ENABLE, S1, S0
HIGH-Level Input Voltage
ENABLE, S1, S0
Input Pull-down Current
ENABLE, S1, S0
IOUT = 1.6mA
VIL
VIH
IIH
Min
Typ
Max
Units
±6.5
0.4
%
0.8
V
V
2
VIH = +0.8V
55
V
80
120
µA
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.
AC Electrical Characteristics(4)
VCC = +12V, CREG = 0.1µF, TA = +25 ºC unless otherwise noted. Bold indicates specification applies over the full
operating temperature range of 0 ºC to +70 ºC.
Symbol
Parameter
Condition
tPOR
Power-on-Reset Delay
tPOCSENSE
Primary OC Detector Default
Response Time to GATE pin
Discharge
tSOCSENSE
Secondary OC Detector
Response Time to GATE Pin
Discharge
Circuit Breaker Reset Delay
Time
ENABLE Low Pulse Width
Shorted CPRIMARY Detection
Time to HW_FLT Latched
Shorted CPRIMARY Detection
Delay after Primary OC
Detection
MOSFET DG Short to
HW_FLT Latched
VVREG ≥ VVREG(UVLOH)
(VVCCSENSE -VSENSE) = 70-mV step;
PRIMARY Pin Floating; and
S[1:0] = H,L
CGATE = 100pF
(VVCCSENSE -VSENSE) = 200-mV step
tCBRESET
tENLPW
tSCPDETECT
tSCPDETPOR
tDG(FET)
tDS(FET)
tDS-SSFAULT2
July 2008
MOSFET DS Short to
HW_FLT Latched
MOSFET DS Short to
HW_FLT Latched
Min
200
Typ
Max
Units
6.5
ms
300
420
µs
0.25
0.5
µs
5
µs
ENABLE Low to I_FLT Low
µs
µs
200
ENABLE = LOW or HIGH;
0.25
VVCCSENSE -VSENSE ≤ VCBP
ENABLE = LOW;
GATEFT(EXT) Asserts HW_FLT
ENABLE = LOW;
SRCFT(EXT) Asserts HW_FLT
ENABLE = HIGH-to-LOW after
steady-state operation
ENABLE = HIGH
DISCH = LOW-to-HIGH
10
6.5
ms
10
µs
10
µs
250
µs
M9999-070108-A
Micrel, Inc.
MIC2310
Symbol
Parameter
Condition
tGLITCH(UVLO)
UVLO & OVP Glitch Filter
Delay Time
VISS Propagation Delay
Time
Overdrive = 50mV
10
µs
VVCCSENSE - VSENSE = 0mV to 60mV
Capacitance from VISS to GND is
100pF
VVCCSENSE - VSENSE = 0mV to 60mV
Capacitance from VISS to GND is
100pF
VVISS 10% to 90%
Overdrive = 250mV
7
µs
25
µs
30
µs
0.25
µs
tVISS(PROP)
tVISS(RISE)
VISS Rise Time
tGLITCH(PWRGD)
PWRGD Glitch Filter Delay
Time
GATE OFF to DISCH Delay
Time
tDLY(DISCH)
Min
Typ
Max
Units
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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Block Diagram
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there is sufficient charge stored on the load capacitor
as evidenced by the output load voltage profile. Note
that the secondary overcurrent detection threshold
(ISOC) is set externally at the controller’s S[1:0] pins.
Once the inrush current exceeds the ISOC threshold,
the circuit breaker trips without delay and the
MIC2310 controller shuts down the output. If the
inrush current profile does not cause either of the OC
detection circuits to trip the circuit breaker and assert
the I_FLT digital output, the controller will assert the
PWRGD digital output when the output load voltage is
higher than the controller’s VPGH threshold voltage and
the VGS of the external MOSFET is higher than the
controller’s VGSPGH threshold voltage. Due to the low
RDS(ON) of the external MOSFET, the output load
voltage rises with the GATE voltage as the VGS of the
MOSFET reaches its threshold voltage. Once the
output load voltage stabilizes near the VCC supply
voltage, the VGS of the external MOSFET increases
above its threshold voltage and eventually exceeds
VGSPGH. The PWRGD output asserts to signal that the
external MOSFET is fully enhanced and ready for the
application of the full load.
Functional Description
Basic Startup Cycle
The basic operation of the MIC2310 is illustrated
below in Figure 2 from a cold-start condition. With the
applied VCC supply low such that the internal VREG
voltage is less than the MIC2310’s internal
VVREG(UVLOH) threshold voltage, all state machines are
reset, all voltage and current monitor subcircuits are
OFF, and the GATE drive circuit is disabled. Digital
inputs and all open-drain digital outputs are inactive.
When the applied VCC supply rises such that the
internal VREG voltage is above the controller’s
VVREG(UVLOH) threshold voltage, the tPOR counter circuit
commences. Once the timer terminates, all internal
state machines are activated, the CPRIMARY short
detection circuit is ON and the DG & DS MOSFET
short detection circuits are ON if ENABLE is LOW.
The I_FLT, PWRGD, and HW_FLT outputs are valid.
Upon the application of an ENABLE LOW-to-HIGH
transition after the tPOR delay, or at the end of the tPOR
delay if ENABLE is already HIGH, a nominal start-up
commences where the dID/dt-controlled inrush current
(by dID/dt = 17.6x10-3 × ISLEW / (RSENSE ×CSLEW)) is
permitted to exceed the IPOC threshold for tPOC, until
+12V, nominal
VCC
VREG = 5V, nominal
VVREGUVLOH
ENABLE
Primary & Secondary
OC Detector Armed
VGSPGH
VGSPGH
GATE
Power
Good
VOUT
ISOC = VCBS/RSENSE
set by S[1:0]
Power
Not Good
VPGL
t POC
ILOAD
dID/dt
Control
by CSLEW
∆t = f(CGATE,VTH(FET))
I SOC
IPOC = VCBP/RSENSE
I POC
Peak inrush current = f(CSLEW, CLOAD)
tPOC = f(C PRIMARY)
0A
PWRGD
tPOR
I_FLT
Figure 2. Basic Startup Cycle
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MIC2310
OC detector has been triggered, the 3mA current
source is first disabled and a 3µA current sink is
enabled to discharge the external CPRIMARY. When
CPRIMARY has discharged below VPRIL, a default timer is
enabled. Once the default timer (tPOCSENSE) times out,
the circuit breaker is tripped, the 3µA current sink is
disabled, and the 3mA current source is enabled to
discharge CPRIMARY back to VREG quickly. Concurrently,
the GATE drive circuit is disabled and a higher
current, fault-mode pull-down current sink is enabled
at the GATE pin. The DISCH output goes high to
(optionally) drive external pull-down circuitry.
In the event that the CPRIMARY pin is left NC
(intentionally or otherwise), the overcurrent timer
default value is tPOCSENSE (250µs typical), as specified
in the ac specification table. Once the circuit breaker
is latched, the I_FLT digital output is asserted and the
PWRGD digital output becomes de-asserted when the
output voltage profile falls below the controller’s VPGL
threshold voltage or the VGS of the external MOSFET
falls below the controller’s VGSPGH threshold voltage.
Primary Overcurrent (OC) Detector Trips Circuit
Breaker and Asserts I_FLT
Figure 3 below illustrates the behavior of the controller
to an OC event after the primary and secondary OC
detection circuits have been armed (upon the
application of an ENABLE LOW-to-HIGH transition
and after tPOR) and steady-state operation has been
achieved. Note that the assertion of the controller’s
PWRGD digital output occurs when the output load
voltage profile is higher than the controller’s VPGH
threshold voltage and the VGS of the external
MOSFET is higher than the controller’s VGSPGH
threshold voltage.
The use of an external CPRIMARY capacitor sets the
response time, tPOC, of the primary OC detector
according to the internal VPRIL threshold voltage and
the CPRIMARY pin discharging current, IPRI, where
tPOC = tPOCSENSE + CPRIMARY ∗ (VPRIL/IPRI). Prior to
triggering the primary OC detector (i.e., when
VVCCSENSE -VSENSE < VCBP), a 3mA current source is
enabled to hold the CPRIMARY pin voltage to the
internally-generated VREG voltage. When the primary
+12V, nominal
VREG = 5V, nominal
VCC
VVREG(UVLOH) = +4.25V
Primary &
Secondary OC
Detectors Armed
ENABLE
VGSPGH
VGSPGH
Power
Not Good
GATE
Power
Good
VOUT
VPGL
VCBS
tPOC
VCBP
VVCCSENSE –VSENSE
0V
PWRGD
tPOR
I_FLT is asserted by Primary OC
Dtector CB Trip after tPOC
I_FLT
tPOC = f(CPRIMARY)
Figure 3. Primary OC Detector Trips Circuit Breaker
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MIC2310
the ac specification table. When the secondary OC
detector has sensed a very large current surge
(VCCSENSE – VSENSE ≥ VCBS), the circuit breaker is
tripped within tSOCSENSE. Concurrently, the GATE drive
circuit is disabled and a higher current, fault-mode
pull-down current sink is enabled at the GATE pin.
The DISCH output goes high to (optionally) drive
external pull-down circuitry.
Once the circuit breaker is latched, the I_FLT digital
output is asserted and the PWRGD digital output
becomes de-asserted when the output voltage profile
falls below the controller’s VPGL threshold voltage or
the VGS of the external MOSFET falls below the
controller’s VGSPGH threshold voltage.
Secondary OC Detector Trips Circuit Breaker and
Asserts I_FLT
Figure 4 illustrates the behavior of the controller to an
OC event after the primary and secondary OC
detection circuits have been armed (upon the
application of an ENABLE LOW-to-HIGH transition
and after tPOR) and steady-state operation has been
achieved. Note that the assertion of the controller’s
PWRGD digital output occurs when the output load
voltage profile is higher than the controller’s VPGH
threshold voltage and the VGS of the external
MOSFET is higher than the controller’s VGSPGH
threshold voltage.
The controller’s secondary OC detection threshold is
set by the status of the controller’s S[1:0] pins and its
response time is internally set at tSOCSENSE as shown in
VCC = 12V, nominal
VREG = 5V, nominal
VVREG(UVLOH) = +4.25V
Figure 4. Secondary OC Detector Trips Circuit Breaker
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MIC2310
voltage profile at no time rises higher than the
controller’s VPGH threshold voltage and the VGS of the
external MOSFET does not rise higher than the
controller’s VGSPGH threshold voltage.
Once the circuit breaker has latched, the I_FLT digital
output is asserted. When the circuit breaker is tripped
by either the primary OC or secondary OC detectors),
applying a HIGH-to-LOW transition on the ENABLE
pin will reset the circuit breaker. At a delay defined by
tCBRESET, the internal circuit breaker is reset and is
indicated when the I_FLT digital output becomes deasserted. The earliest a LOW-to-HIGH transition at
ENABLE is permitted to initiate a new start-up
sequence is defined by the tENLPW timing specification.
Charging Load by dID/dt – Primary OC Trips CB
after tPOC and CB Reset by Toggling ENABLE
HIGH-to-LOW
Figure 5 illustrates the behavior of the controller to an
OC event after the primary and secondary OC
detection circuits have been armed (upon the
application of an ENABLE LOW-to-HIGH transition
and after tPOR). In this example, the load capacitor is
charged at a controlled dID/dt rate. Steady-state
operation is not achieved as the controlled inrush
profile causes the primary OC detector to trigger at
IPOC and continues charging when the tPOCSENSE timer
terminates. Note that the controller’s PWRGD digital
output does not assert because the output load
VCC = 12V, nominal
VREG = 5V, nominal
VVREG(UVLOH) = +4.25V
Figure 5. dID/dt Load Charge Profile w/ Primary OC Circuit Breaker (CB) Trip w/ CB Reset
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MIC2310
The use of an external CRETRY capacitor sets the autoretry time, tRETRY, according to the internal VRETRYH
threshold voltage and the CRETRY pin charging
current, IRETRYUP [tRETRY = CRETRY * (VRETRYH/IRETRYUP)].
Prior to the tripping of the OC circuit breaker, a 3mA
current sink is enabled holding the CRETRY pin
voltage at 0V. When the OC circuit breaker has been
tripped, the 3mA current sink is disabled and a 3µA
current source is enabled to charge the external
CRETRY capacitor. When CRETRY has charged above
VRETRYH, the circuit breaker is reset such that the
I_FLT digital output is de-asserted. Additionally, the
3µA current source is disabled and the 3mA current
sink is enabled to discharge the CRETRY pin voltage
back to 0V. When CRETRY has discharged below
VRETRYL, the GATE drive circuit is re-enabled and the
DISCH output returns low. For the case of a persistent
overcurrent load, the controller will continuously cycle
between starting up into an OC condition that trips the
circuit breaker and the auto-retry time before the
circuit breaker is reset.
Primary OC Trips Circuit Breaker (CB) and CB
Resets with CRETRY (Auto-Retry Timing Capacitor)
Figure 6 illustrates the behavior of the controller to a
primary OC event when a CRETRY capacitor is used to
automatically reset the circuit breaker. The automatic
reset operation is the same for the case of a
secondary OC event. In this example, the primary and
secondary OC detection circuits have been armed
(upon the application of an ENABLE LOW-to-HIGH
transition and after tPOR) and the load capacitor is
charged at a controlled dID/dt rate. Note that in this
diagram, ENABLE is tied to VCC and rises with VCC.
Steady-state operation is achieved as the controller’s
PWRGD digital output is asserted when the output
load voltage profile is higher than the controller’s VPGH
threshold voltage and the VGS of the external
MOSFET is higher than the controller’s VGSPGH
threshold voltage.
When the primary OC detector has been triggered by
an output current exceeding IPOC for a time tPOC, the
circuit breaker is tripped, the GATE drive circuit is
disabled, the fault-mode pull-down current sink is
enabled at the GATE pin, the DISCH output goes
high, and the I_FLT digital output becomes asserted.
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MIC2310
VCC = 12V, nominal
VREG = 5V, nominal
VCC & VREG
VVREG(UVLOH)
ENABLE
VGSPGH
VGSPGH
GATE
VPGL
VPGH
VOUT
tPOC
IPOC
ILOAD
tRETRY
CRETRY
tPOR
PWRGD
I_FLT
DISCH
Figure 6. Primary Overcurrent Fault with Auto-Retry to Reset the Circuit Breaker
current sink is not capable of holding the voltage at 0V
as the GATE voltage tracks the MOSFET’s DRAIN
voltage. The voltage monitor circuit at the controller’s
GATE pin will be triggered once the GATE voltage
crosses the VGATEFT(EXT) threshold voltage. The
HW_FLT digital output is subsequently asserted within
a delay approximately equal to the delay in the logic
circuits – no additional timing circuit is required. To
clear the latched GATE voltage monitor circuit and to
reset the HW_FLT digital output, the applied VCC
supply voltage must fall such that VREG is below the
controller’s VVREG(UVLOL) threshold voltage.
HW_FLT Digital Output Asserted by a MOSFET DG
Short with ENABLE = LOW
In order to protect the system from the result of the
installation of a damaged MOSFET on the PCB, the
controller incorporates a MOSFET shorted DG
detection scheme whose operation is described in
Figure 7. With the applied VCC supply high such that
the internal VREG voltage is above the controller’s
VVREG(UVLOH) threshold voltage, an elapsed POR timer,
and with the ENABLE input LOW, a weak current sink
at the GATE pin attempts to hold the GATE voltage at
0V. If there is a DG short on the MOSFET, the weak
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MIC2310
Figure 7. Hardware Fault Detection of a MOSFET DG Short with ENABLE = LOW
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MIC2310
at 0V as the SOURCE voltage tracks the MOSFET’s
DRAIN voltage. The voltage monitor circuit at the
controller’s SOURCE pin will be triggered once the
SOURCE voltage crosses the VSRCFT(EXT) threshold
voltage. The HW_FLT digital output is subsequently
asserted within a delay approximately equal to the
delay in the logic circuits – no additional timing circuit
is required. To clear the latched source voltage
monitor circuit and to reset the HW_FLT digital output,
the applied VCC supply voltage must fall such that
VREG is below the controller’s VVREG(UVLOL) threshold
voltage.
HW_FLT Digital Output Asserted by MOSFET DS
Short with ENABLE = LOW
In order to protect the system from the result of the
installation of a damaged MOSFET on the PCB, the
controller incorporates a MOSFET shorted DS
detection scheme whose operation is described in
Figure 8. With the applied VCC supply high such that
the internal VREG voltage is above the controller’s
VVREG(UVLOH) threshold voltage, an elapsed POR timer,
and with the ENABLE input LOW, a voltage monitor
circuit for the controller’s SOURCE pin is enabled. If
there is a DS short on the MOSFET, the external load
on the MOSFET is not capable of holding the voltage
Figure 8. Hardware Fault Detection of a MOSFET DS Short with ENABLE = LOW
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MIC2310
current sink is enabled, the DISCH output goes high,
and the tDS-SSFAULT timer is started. With the ENABLE
input LOW, a voltage monitor circuit for the controller’s
SOURCE pin (i.e., VOUT) is enabled. If there is a DS
short, the voltage at the source will not drop to 0V
even though the GATE is OFF. If the output voltage at
the SOURCE pin remains higher than the controller’s
VSRCFT(EXT) threshold voltage when the tDS-SSFAULT timer
terminates, the HW_FLT digital output is asserted. To
repair the damaged MOSFET and to reset the
HW_FLT digital output and the controller, the service
processor instructs the main supply to turn off the VCC
supply voltage to the controller such that VREG falls
below the controller’s VVREG(UVLOL) threshold voltage.
HW_FLT Asserted by MOSFET DS Short after
Steady-state Operation then ENABLE = HIGH-toLOW
Figure 9 illustrates the behavior of the controller to a
shorted DS MOSFET condition after steady-state
operation is achieved via a nominal start-up. Note that
the load capacitor at start-up was charged in a
controlled dID/dt mode and assertion of the controller’s
PWRGD digital output occurs when the output load
voltage profile is higher than the controller’s VPGH
threshold voltage and the VGS of the external
MOSFET is higher than the controller’s VGSPGH
threshold voltage. Upon the application of a HIGH-toLOW transition on ENABLE by the service processor,
the GATE drive circuit is disabled, the weak GATE
Figure 9. Hardware Fault by a MOSFET DS Short after Steady-State Operation
(ENABLE = HIGH-to-LOW)
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MIC2310
voltage monitor circuit for the controller’s SOURCE
pin is also enabled. If there is a DS short, the voltage
at the source will not drop to 0V even though the
GATE is OFF. If the output voltage at the SOURCE
pin remains higher than the controller’s VSRCFT(EXT)
threshold voltage when the tDS-SSFAULT timer
terminates, the HW_FLT digital output is asserted. To
repair the damaged MOSFET and to reset the
HW_FLT digital output and the controller, the service
processor instructs the main supply to turn off the VCC
supply voltage to the controller such that VREG falls
below the controller’s VVREG(UVLOL) threshold voltage.
HW_FLT Asserted by MOSFET DS Short after
Steady-state Operation then a Fault Condition
Figure 10 illustrates the behavior of the controller to a
shorted DS MOSFET condition after steady-state
operation is achieved via a nominal start-up. With the
occurrence of one of the following fault conditions –
UVLO, OVP, primary OC, secondary OC, open
LOADSENSE, or open GNDSENSE - the GATE drive
circuit is disabled, the GATE fault-mode pull-down
current sink is enabled, the DISCH output goes high,
and the tDS-SSFAULT timer is started. The occurrence of
a primary OC fault condition is shown here. The
VCC & VREG
VVREG(UVLOH)
VVREG(UVLOL)
VVREG(UVLOH)
ENABLE
VGSPGH
VGSPGH
GATE
DG Short
VPGL
VPGH
VOUT
VSRCFT(EXT)
tPOC
ILOAD
tPOR
tPOR
PWRGD
I_FLT
tDS-SSFAULT
HW_FLT
DISCH
Figure 10. HW_FLT Asserted by a MOSFET DS Short after Steady-State Operation then a Fault Condition
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RSENSE short detection at low current, a minimum VDS
of ∆VDS(FET) must exist across the external MOSFET
for a shorted sense resistor to be detected. For larger
values of VDS across the external MOSFET generated
by higher load currents, the ∆VRSENSE threshold
voltage for the detection of an RSENSE short follows the
equation ∆VRSENSE = 0.5 * (VDS - ∆VDS(FET)). If there
exists a short across the sense resistor such that VRS
drops below the ∆VRSENSE threshold voltage, then an
internal circuit breaker is tripped, the GATE drive
circuit is disabled, the GATE fault-mode pull-down
current sink is enabled, the DISCH output goes high,
and the HW_FLT digital output is asserted. To repair
the damaged sense resistor and reset the HW_FLT
digital output, the service processor instructs the main
supply to turn off the VCC supply voltage to the
controller such that VREG falls below the controller’s
VVREG(UVLOL) threshold voltage.
Shorted RSENSE Detector Trips CB and Asserts
HW_FLT
In order to protect the system from the result of the
installation of a shorted sense resistor on the PCB,
which would increase the effective OC detection
thresholds to unsafe levels, the controller incorporates
a shorted RSENSE detection scheme whose operation is
described in Figure 11. The RSENSE detection circuitry
is enabled upon the application of an ENABLE LOWto-HIGH transition, an elapsed POR timer, and the
VGS of the external MOSFET being higher than the
controller’s VGSPGH threshold voltage. Note that for the
case of a shorted sense resistor, dID/dt control of the
inrush current is disabled and the controller defaults to
dVGATE/dt control of the GATE voltage.
An RSENSE short is detected by comparing the VRS
voltage drop across the sense resistor
(VCCSENSE-VSENSE) to the VDS voltage drop across the
external MOSFET (VSENSE-VSOURCE). To avoid a false
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MIC2310
VCC & VREG
VVREG(UVLOH)
VVREG(UVLOL)
VVREG(UVLOH)
ENABLE
VGSPGH
GATE
VPGH
VOUT
VDS(FET)
DS(FET)
RSENSE
VRS
tPOR
tPOR
PWRGD
HW_FLT
DISCH
Figure 11. Shorted RSENSE Trips Circuit Breaker and Asserts HW_FLT
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capacitor value, one which keeps the primary OC
response time, tPOC, less than 0.5s, CPRIMARY charges
above VPRIH before the POR timer terminates and
normal operation commences. However, if the
CPRIMARY pin is shorted to GND or CPRIMARY is too
large, as in this timing diagram, the POR timer
terminates before CPRIMARY charges above VPRIH and a
shorted CPRIMARY is detected. When a CPRIMARY short is
detected, the GATE drive circuit and the DISCH
output are not affected, however, the HW_FLT digital
output is asserted. To repair the damaged CPRIMARY
capacitor and reset the HW_FLT digital output, the
service processor instructs the main supply to turn off
the VCC supply voltage to the controller such that VREG
falls below the controller’s VVREG(UVLOL) threshold
voltage.
Shorted CPRIMARY Detector Asserts HW_FLT at
Start-up
In order to protect the system from the result of the
installation of a shorted or excessively large CPRIMARY
capacitor on the PCB, the controller incorporates a
shorted CPRIMARY detection scheme. A shorted
CPRIMARY pin or an excessively large CPRIMARY
capacitor will impact the primary OC detection time,
tPOC. The operation of the shorted CPRIMARY detection
scheme at start-up is described in Figure 12. Prior to
power-up, the CPRIMARY pin is discharged to 0V. As
the applied VCC supply and the internal VREG voltage
rise, a 3mA current source is applied to the
CPRIMARY pin to charge CPRIMARY to VREG. When the
internal VREG voltage is above the controller’s
VVREG(UVLOH) threshold voltage, the tPOR timer is
initiated. For the case of a reasonable CPRIMARY
VCC & VREG
VVREG(UVLOH)
VVREG(UVLOH)
VVREG(UVLOL)
ENABLE
VGSPGH
VGSPGH
GATE
VPGH
VPGL
VOUT
ILOAD
SMALLER CPRIMARY
CPRIMARY
VPRIH
VPRIH
CPRIMARY TOO LARGE
tPOR
tPOR
PWRGD
HW_FLT
DISCH
Figure 12. Shorted CPRIMARY Detector Asserts HW_FLT at Start-up
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circuit remains enabled and the DISCH output
remains low such that the external MOSFET remains
ON, however, the HW_FLT digital output is asserted.
To repair the damaged CPRIMARY capacitor and reset
the HW_FLT digital output, the service processor
instructs the main supply to turn off the VCC supply
voltage to the controller such that VREG falls below the
controller’s VVREG(UVLOL) threshold voltage.
Shorted CPRIMARY Detector Asserts HW_FLT during
Steady-state
Figure 13 illustrates the behavior of the controller to a
shorted CPRIMARY capacitor condition after steady-state
operation is achieved via a nominal start-up. If a
CPRIMARY short occurs during steady-state operation,
the CPRIMARY pin voltage will drop below the VPRIL
threshold voltage and a shorted CPRIMARY is detected.
When a CPRIMARY short is detected, the GATE drive
VCC & VREG
VVREG(UVLOH)
VVREG(UVLOH)
VVREG(UVLOL)
ENABLE
VGSPGH
VGSPGH
GATE
VPGH
VPGL
VOUT
ILOAD
SHORTED CPRIMARY
CPRIMARY
VPRIH
CPRIMARY REPAIRED
VPRIH
VPRIL
tPOR
tPOR
PWRGD
HW_FLT
DISCH
Figure 13. Shorted CPRIMARY Detector Asserts HW_FLT During Steady-State
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MIC2310
when the CPRIMARY short detection circuitry is reenabled.
In the timing diagram, CPRIMARY becomes shorted
during the primary OC event. When the CPRIMARY
pin voltage falls below VPRIL, the tPOCSENSE timer is
enabled. Once this timer times out, the circuit breaker
is tripped, I_FLT is asserted, the GATE drive circuitry
is disabled, the GATE fault-mode pull-down current
sink is enabled, and the DISCH output goes high. As
the external MOSFET is turned OFF, the output
current drops and an overcurrent condition is no
longer detected. This initiates the tSCPDETPOR timer.
Since CPRIMARY does not charge back up above VPRIH
before this timer expires, HW_FLT is asserted after
the tSCPDETPOR time. To repair the damaged CPRIMARY
capacitor and reset the HW_FLT digital output, the
service processor instructs the main supply to turn off
the VCC supply voltage to the controller such that VREG
falls below the controller’s VVREG(UVLOL) threshold
voltage.
Shorted CPRIMARY Detector Asserts HW_FLT After
Primary OC Event
The diagram in Figure 14 illustrates the behavior of
the controller to a shorted CPRIMARY capacitor condition
after steady-state operation is achieved via a nominal
start-up and after a primary OC event has occurred.
As described previously, during a primary OC event,
the CPRIMARY capacitor is discharged as part of setting
the primary OC detector response time, tPOC. In order
to prevent a false CPRIMARY short detection from
occurring while the CPRIMARY pin is being
intentionally discharged, the CPRIMARY short detection
circuit is disabled when the primary OC detector
detects an overcurrent. In addition, the CPRIMARY short
detection circuit is not re-enabled until after a time
delay, tSCPDETPOR, once the primary OC detector no
longer detects an overcurrent. This delay time should
allow a capacitor of reasonable size to be charged
back up above VPRIH, even if it has been discharged to
0V, such that a false CPRIMARY short is not indicated
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MIC2310
VCC & VREG
VVREG(UVLOH)
VVREG(UVLOH)
VVREG(UVLOL)
ENABLE
VGSPGH
VGSPGH
GATE
VPGH
VOUT
tPOCSENSE
tPOC
IPOC
ILOAD
SHORTED CPRIMARY
CPRIMARY REPAIRED
VPRIH
CPRIMARY
VPRIH
VPRIL
tPOR
tSCPDETPOR
tPOR
PWRGD
I_FLT
HW_FLT
DISCH
Figure 14. Shorted CPRIMARY Detector Asserts HW_FLT after Primary OC Event
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LOADSENSE pin is open, the LOADSENSE voltage
will remain at a lower voltage due to the load of other
internal circuitry. An open LOADSENSE pin is
detected by comparing the voltage at the SOURCE
pin to the voltage at the LOADSENSE pin. Once the
voltage at the SOURCE pin differs from the voltage at
the LOADSENSE pin by VTHLOADSENSE, a circuit
breaker is tripped, the GATE drive circuitry is
disabled, the GATE fault-mode pull-down current sink
is enabled, and the DISCH output goes high. This
circuit breaker can be reset, such that the GATE drive
circuitry can be re-enabled, by either a HIGH-to-LOW
transition on ENABLE or turning off the VCC supply
voltage to the controller such that VREG falls below the
controller’s VVREG(UVLOL) threshold voltage.
Open LOADSENSE Detector Trips CB
In order to protect the system from the result of an
open LOADSENSE pin, the controller incorporates an
open LOADSENSE detection scheme. An open
LOADSENSE pin could result in the effective primary
OC detection threshold being at an unsafe level. The
timing diagram in Figure 15 describes the operation of
this function. With the applied VCC supply high such
that the internal VREG voltage is above the controller’s
VVREG(UVLOH) threshold voltage, an elapsed POR timer,
and with the application of an ENABLE LOW-to-HIGH
transition, the GATE drive circuitry is enabled and the
GATE voltage begins to rise. As the external
MOSFET turns ON, the SOURCE voltage begins to
rise also. Normally, the LOADSENSE voltage would
rise with the SOURCE voltage. However, if the
VCC & VREG
VVREG(UVLOH)
VVREG(UVLOL)
VVREG(UVLOH)
ENABLE
VGSPGH
GATE
VPGH
VTHLOADSENSE
VOUT
ILOAD
LOADSENSE CONNECTED
LOADSENSE OPEN
LOADSENSE
tPOR
tPOR
PWRGD
DISCH
Figure 15. Open LOADSENSE Detector Trips CB
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would remain at 0V. However, if the GNDSENSE pin
is open, the GNDSENSE voltage will rise due to the
load of other internal circuitry. An open GNDSENSE
pin is detected by comparing the voltage at the
GNDSENSE pin to the voltage at the AGND pin. Once
the voltage at the GNDSENSE pin differs from the
voltage at the AGND pin by VTHGNDSENSE, a circuit
breaker is tripped, the GATE drive circuitry is
disabled, the GATE fault-mode pull-down current sink
is enabled, and the DISCH output goes high. This
circuit breaker can be reset, such that the GATE drive
circuitry can be re-enabled, by either a HIGH-to-LOW
transition on ENABLE or turning off the VCC supply
voltage to the controller such that VREG falls below the
controller’s VVREG(UVLOL) threshold voltage.
Open GNDSENSE Detector Trips CB
In order to protect the system from the result of an
open GNDSENSE pin, the controller incorporates an
open GNDSENSE detection scheme. An open
GNDSENSE pin could result in the effective primary
OC detection threshold being at an unsafe level. The
timing diagram in Figure 16 describes the operation of
this function. With the applied VCC supply high such
that the internal VREG voltage is above the controller’s
VVREG(UVLOH) threshold voltage, an elapsed POR timer,
and with the application of an ENABLE LOW-to-HIGH
transition, the GATE drive circuitry is enabled and the
GATE voltage begins to rise. As the external
MOSFET turns ON, the SOURCE voltage begins to
rise also and the LOADSENSE voltage follows the
SOURCE voltage. Normally, the GNDSENSE pin
VCC & VREG
VVREG(UVLOH)
VVREG(UVLOL)
VVREG(UVLOH)
ENABLE
VGSPGH
GATE
VPGH
VOUT
ILOAD
GNDSENSE OPEN
VTHGNDSENSE
GNDSENSE
GNDSENSE CONNECTED
tPOR
tPOR
PWRGD
DISCH
Figure 16. Open GNDSENSE Detector Trips CB
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VOVPH threshold voltage, the GATE drive circuitry is
disabled, the GATE fault-mode pull-down current sink
is enabled, and the DISCH output goes high.
Increasing VCC such that the voltage applied to the
UVLO pin increases above VUVLOH or decreasing VCC
such that the voltage applied to the OVP decreases
below VOVPL re-enables the GATE drive circuit and
forces the DISCH output low, allowing the controller to
return to normal operation.
UVLO and OVP Operation
The system can be protected against an undervoltage condition or an over-voltage condition on the
VCC supply by using an external resistor divider and
the UVLO and OVP pins, respectively. Figure 17
illustrates the timing of the GATE and digital pin
outputs when the input supply crosses the UVLO and
OVP thresholds. When the voltage applied to the
UVLO pin is less than the VUVLOL threshold voltage or
the voltage applied to the OVP pin is greater than the
VCC & VREG
VVREG(UVLOH)
ENABLE
VGSPGH
VGSPGH
VGSPGH
GATE
VPGL
VPGH
VPGH
VPGL
VPGH
VOUT
ILOAD
UVLOL
UVLO
UVLOH
OVPH
OVPL
OVP
tPOR
PWRGD
DISCH
Figure 17. UVLO and OVP Operation
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MIC2310
digital output is asserted and the VISS output
becomes active. The current flowing in the external
sense resistor is determined by sensing the voltage
across the sense resistor (VCCSENSE-VSENSE). As the
output current varies under changing load conditions,
VCCSENSE-VSENSE also varies and the VISS output
voltage changes proportionally according to VISS(SENS).
When the external MOSFET is disabled, either by a
HIGH-to-LOW transition on ENABLE or due to a fault
condition, the VGS of the external MOSFET falls below
the controller’s VGSPGH threshold voltage. This causes
the PWRGD digital output to be de-asserted and the
VISS output to be disabled.
VISS Output Operation
The VISS output provides a voltage which is
proportional to the output current flowing in the
external sense resistor. Figure 18 illustrates the
operation of this output. With the applied VCC supply
high such that the internal VREG voltage is above the
controller’s VVREG(UVLOH) threshold voltage, an elapsed
POR timer, and with the application of an ENABLE
LOW-to-HIGH transition, the GATE drive circuitry is
enabled. When the output load voltage profile is
higher than the controller’s VPGH threshold voltage and
the VGS of the external MOSFET is higher than the
controller’s VGSPGH threshold voltage, the PWRGD
VCC & VREG
VVREG(UVLOH)
VVREG(UVLOL)
ENABLE
VGSPGH
VGSPGH
GATE
VPGH
VPGL
VOUT
ILOAD
VISS
tPOR
PWRGD
DISCH
Figure 18. VISS Operation
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components are vital with regards to the shorted
RSENSE detection scheme such that the values of each
need to be chosen such that variations in RDS(ON) and
RSENSE over process, supply, and temperature does
not result in a false RSENSE short detection. In short,
the value of RDS(ON) of the external MOSFET should
be selected to not exceed twice the value of RSENSE
over process, supply, and temperature, to avoid the
generation of a false RSENSE short detection.
Applications Information
The MIC2310 can be configured to address powerlimiting applications other than the 240-VA power
control (UL60950 Safe Power Handling Systems).
There are two key requirements to consider in
selecting the external components for use in various
power-limit applications: 1) The value (and tolerance)
of the RSENSE current sensing resistor; and 2) The
RDS(ON) of the external Power MOSFET. These two
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Package Information
24-Pin TSSOP (TS)
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.
© 2008 Micrel, Incorporated.
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