FREESCALE MCZ34652EF

Freescale Semiconductor
Advance Information
Document Number: MC34652
Rev. 8.0, 2/2007
2.0 A Negative Voltage Hot
Swap Controller with Enhanced
Programmability
34652
The 34652 is a highly integrated - 48 V hot swap controller with an
internal Power MOSFET. It provides the means to safely install and
remove boards from live - 48 V backplanes without having to power
down the entire system. It regulates the inrush current, from the
supply to the load’s filter capacitor, to a user-programmable limit,
allowing the system to safely stabilize. A disable function allows the
user to disable the 34652 manually or through a microprocessor and
safely disconnect the load from the main power line.
The 34652 has active high and active low power good output
signals that can be used to directly enable a power module load.
Programmable under- and overvoltage detection circuitry monitors
the input voltage to check that it is within its operating range.
A programmable start-up delay timer ensures that it is safe to turn on
the Power MOSFET and charge the load capacitor.
A two-level current limit approach to controlling the inrush current
and switching on the load limits the peak power dissipation in the
Power MOSFET. Both current limits are user programmable.
Features
• Integrated Power MOSFET and Control IC in a Small Outline
Package
• Input Voltage Operation Range from -15 V to - 80 V
• Programmable Overcurrent Limit with Auto Retry
• Programmable Charging Current Limit Independent of Load
Capacitor
• Programmable Start-Up and Retry Delay Timer
• Programmable Overvoltage and Undervoltage Detection
• Active High and Low Power Good Output Signals
• Thermal Shutdown
• Pb-Free Packaging Designated by Suffix Code EF
HOT SWAP
SCALE 2:1
EF SUFFIX (PB-Free)
98ASB42566B
16-PIN SOICN
ORDERING INFORMATION
Device
MCZ34652EF/ R2
DISABLE
PG
Application
Dependent
VPWR
PG
System
Power
Supply
(Backplane)
-48 V
UV
VOUT
Load
OV
VIN
ICHG
Optional
External
Components
ILIM
TIMER
Optional
External
Components
Figure 1. 34652 Simplified Application Diagram
* This document contains certain information on a new product.
Specifications and information herein are subject to change without notice.
© Freescale Semiconductor, Inc., 2007. All rights reserved.
Package
- 40°C to 85°C
16 SOICN
MC34652EF/ R2
34652
GND
Temperature
Range (TA)
INTERNAL BLOCK DIAGRAM
INTERNAL BLOCK DIAGRAM
Referenced VPWR
Logic
DISABLE
Timer
and
External
Resistors
Detection
Adjustable Oscillator
and
Startup Delay Timer
Fixed
Oscillator
TIMER
VPWR
PG
-
UVLO
1.3 V +
Logic
-
UV
PG
UV
1.3 V +
+
OV
OV
1.3 V -
VIN
Thermal
Shutdown
ILIM
3.1 V
8.0 µA
External
Resistors
Detection
Programmable
Current Limit
Gate Control
Driver
ICHG
Sensor MOSFET
VIN
Power MOSFET
VOUT
Figure 2. 34652 Simplified Internal Block Diagram
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Analog Integrated Circuit Device Data
Freescale Semiconductor
PIN CONNECTIONS
PIN CONNECTIONS
VIN
1
16
VIN
PG
2
15
ICHG
PG
3
14
ILIM
VOUT
4
13
DISABLE
VOUT
5
12
VPWR
TIMER
6
11
UV
NC
7
10
OV
VIN
8
9
VIN
Figure 3. 16-SOICN Pin Connections
Table 1. 16-SOICN Pin Definitions
A functional description of each pin can be found in the FUNCTIONAL PIN DESCRIPTION section beginning on page 10.
Pin
Pin Name
Formal Name
Definition
1, 8, 9, 16
VIN
Negative Supply
Input Voltage
This is the most negative power supply input. All pins except DISABLE are referenced
to this input.
2
PG
Power Good Output
(Active High)
This is an active high power good output signal. This pin is referenced to VIN.
3
PG
Power Good Output
(Active Low)
This is an active low power good output signal. This pin is referenced to VIN.
4, 5
VOUT
Output Voltage
6
TIMER
Start-Up and Retry
Delay Timer
7
NC
No Connect
10
OV
Overvoltage Control
This pin is used to set the upper limit of the input voltage operation range.
11
UV
Undervoltage Control
This pin is used to set the lower limit of the input voltage operation range.
12
VPWR
Positive Supply
Input Voltage
13
DISABLE
Disable Input Control
This pin is used to easily disconnect or connect the load from the main power line by
disabling or enabling the 34652. It can also be used to reset the fault conditions that
cause a “Power No Good” signal. This pin is referenced to VPWR.
14
ILIM
Current Limit Control
This pin is used to set the overcurrent limit during normal operation.
15
ICHG
Charging Current
Limit Control
This pin is the drain of the internal Power MOSFET and supplies a current limited voltage
to the load.
This input is used to control the time base used to generate the timing sequences at
start-up and the retry delay when the device experiences any fault.
Not connected.
This is the most-positive power supply input. The load connects between this pin and the
VOUT pin.
This pin is used to set the load’s input capacitor charging current limit, hence limiting the
inrush current to a known constant value.
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
3
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 2. Maximum Ratings
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or
permanent damage to the device.
Ratings
Symbol
Value
Unit
VPWR
85
V
EMOSFET
Varies (1)
mJ
IO (CONT)
2.0
A
ELECTRICAL RATINGS
Power Supply Voltage
Power MOSFET Energy Capability
Continuous Output Current
(2)
Maximum Voltage
V
DISABLE Pin
—
VIN - 0.3 to VPWR + 5.5
UV Pin
—
7.0
OV, ILIM, ICHG, and TIMER Pins
—
5.0
PG Pin (VPG - VIN)
—
85
PG Pin (VPG - VIN)
—
85
All Pins Minimum Voltage
—
- 0.3
V
PG, PG Maximum Current
—
Internally Limited
A
VESD3
± 2000
VESD4
± 200
TSTG
- 65 to 150
TA
- 40 to 85
TJ
- 40 to 160
ESD Voltage, All Pins (3)
Human Body Model
Machine Model
V
THERMAL RATINGS
Storage Temperature
°C
Operating Temperature
Ambient
Junction
(4)
°C
Notes
1. Refer to the section titled Power MOSFET Energy Capability on page 23 for a detailed explanation on this parameter.
2. Continuous output current capability so long as TJ is ≤ 160°C.
3.
ESD1 testing is performed in accordance with the Human Body Model (CZAP = 100pF, RZAP = 1500 Ω), ESD2 testing is performed in
accordance with the Machine Model (CZAP = 200 pF, RZAP = 0 Ω).
4.
The limiting factor is junction temperature, taking into account power dissipation, thermal resistance, and heatsinking.
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Analog Integrated Circuit Device Data
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ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 2. Maximum Ratings (continued)
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or
permanent damage to the device.
Ratings
Symbol
Value
Unit
TPPRT
Note 6
°C
RθJA
103
RθJMA
65
ELECTRICAL RATINGS
Peak Package Reflow Temperature During Reflow (5), (6)
Thermal Resistance (7)
, (8)
Junction-to-Ambient, Single-Layer Board
°C/W
(9)
Junction-to-Ambient, Four-Layer Board (10)
Notes
5. Pin soldering temperature limit is for 10 seconds maximum duration. Not designed for immersion soldering. Exceeding these limits may
cause malfunction or permanent damage to the device.
6. Freescale’s Package Reflow capability meets Pb-free requirements for JEDEC standard J-STD-020C. For Peak Package Reflow
Temperature and Moisture Sensitivity Levels (MSL),
Go to www.freescale.com, search by part number [e.g. remove prefixes/suffixes and enter the core ID to view all orderable parts. (i.e.
MC33xxxD enter 33xxx), and review parametrics.
7. Refer to the section titled Thermal Shutdown on page 16 for more thermal resistance values under various conditions.
8. The VOUT and VIN pins comprise the main heat conduction paths.
9. Per SEMI G38-87 and JEDEC JESD51-2 with the single-layer board (JESD51-3) horizontal.
10. Per JEDEC JESD51-6 with the board (JESD51-7) horizontal. There are no thermal vias connecting the package to the two planes in the
board.
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Analog Integrated Circuit Device Data
Freescale Semiconductor
5
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics
Characteristics noted under conditions 15 V ≤ VPWR ≤ 80 V and - 40°C ≤ TA ≤ 85°C. All voltages are referenced to VIN unless
otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
VPWR
15
—
80
V
IIN
—
900
1400
µA
POWER SUPPLY PIN (VPWR)
Supply Voltage
Supply Current, Device Enabled, Default Mode, Normal Operation
(11)
Undervoltage Lockout Threshold (UVLO)
V
Rising
VUVLOR
7.0
8.0
9.0
Falling
VUVLOF
6.0
7.0
8.0
VUVLOHY
—
1.0
—
Rising
VUV(ON)
—
38
—
Falling
VUV(OFF)
—
37
—
VUVHY
—
1.0
—
Hysteresis
UNDERVOLTAGE CONTROL
UV Threshold (Default)
Hysteresis
V
UV Comparator Threshold
Rising
Hysteresis
VUVC
—
1.3
—
V
VUVCHY
—
34
—
mV
IUVLG
—
—
1.0
µA
—
—
—
500
kΩ
UV Input Leakage Current
Maximum Value of the Series Resistance Between UV and VPWR Pins
OVERVOLTAGE CONTROL
OV Threshold (Default)
V
Rising
VOV (OFF)
—
78
—
Falling
VOV (ON)
—
76
—
VOVHY
—
2.0
—
Hysteresis
OV Comparator Threshold
Rising
Hysteresis
VOVC
—
1.3
—
V
VOVCHY
—
34
—
mV
IOVLG
—
—
1.0
µA
—
—
—
500
kΩ
OV Input Leakage Current
Maximum Value of the Series Resistance Between UV and VPWR Pins
Notes
11. The supply current depends on operation mode and can be calculated as follows:
•Start-Up Mode: IIN = 539 µA + 548 µ * ICHG(A) + 216 µ * ILIM(A) + VPWR(V) / 460(kΩ)
•Normal Mode: IIN = 539 µA + 240 µ * ILIM(A) + 288 µ * ILOAD(A) + VPWR(V) / 460(kΩ)
•Overcurrent Mode: IIN = 539 µA + 612 µ * ILIM(A) + VPWR(V) / 460(kΩ)
•Disable Mode: IIN = 539 µA + 240 µ * ILIM(A) + IDIS(µA) + VPWR(V) / 460(kΩ)
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Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 15 V ≤ VPWR ≤ 80 V and - 40°C ≤ TA ≤ 85°C. All voltages are referenced to VIN unless
otherwise noted.
Characteristic
DISABLE INPUT CONTROL PIN (DISABLE)
Symbol
Min
Typ
Max
Unit
(12)
DISABLE Input Voltage
V
Inactive State
VDISL
VPWR - 1.2
—
VPWR + 1.2
Active State, Positive Signal
VDISHP
VPWR + 2.0
—
—
Active State, Negative Signal
VDISHN
—
—
VPWR - 2.0
VDIS = VPWR + 3.3 V
20
60
180
VDIS = VPWR - 3.3 V
-20
- 60
-180
VDIS = VIN
- 50
-150
- 250
DISABLE Input Current
µA
IDIS
CURRENT LIMIT CONTROL PINS (ILIM, ICHG)
Overcurrent Limit in Steady State
ILIM
A
Default
—
1.0
—
Maximum with External Resistor
—
2.25
—
Minimum with External Resistor
—
0.35
—
Default
—
0.1
—
Maximum with External Resistor
—
0.5
—
Minimum with External Resistor
—
0.05
—
Current Limit During Start-Up
ICHG
A
Short Circuit Current Limit
ISHORT
—
5.0
—
A
ILIM Current Limit Hysteresis
ILIMHY
—
12
—
%
ILIM Current Limit Accuracy
ILIMCLA
-20
—
20
%
ICHG Current Limit Accuracy
ICHGCLA
- 35
—
35
%
VILIM
—
3.1
—
V
ILIM to RILIM Setting Constant
ILIMCNS
—
129
—
A * kΩ
ICHG Reference Current
ICHGOUT
—
- 8.0
—
µA
ICHGCNS
—
335
—
kΩ/A
—
—
0.5
—
—
10
—
—
7.0
ILIM Pin Voltage
ICHG to RICHG Setting Constant
POWER GOOD OUTPUT PINS (PG, PG)
(13)
Power Good Output Low Voltage
VPGL
IPG or IPG = 1.6 mA
Power Good Leakage Current
IPGLG
Power Good Current Limit
IPGCL
VPG or VPG = 3.0 V
V
µA
mA
Notes
12. Referenced to VPWR.
13. Referenced to VIN.
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Analog Integrated Circuit Device Data
Freescale Semiconductor
7
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 15 V ≤ VPWR ≤ 80 V and - 40°C ≤ TA ≤ 85°C. All voltages are referenced to VIN unless
otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
VTIMER
—
1.3
—
V
IOUTLG
—
—
50
µA
RDS(ON)
—
144
—
mΩ
TSD
—
160
—
°C
TSDHY
—
25
—
°C
START-UP AND RETRY DELAY TIMER (TIMER)
TIMER Pin Voltage
OUTPUT VOLTAGE PIN (VOUT)
VOUT Leakage Current
POWER MOSFET
ON Resistance @ 25°C
THERMAL SHUTDOWN
Thermal Shutdown Temperature
Thermal Shutdown Temperature Hysteresis
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ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics
Characteristics noted under conditions 15 V ≤ VPWR ≤ 80 V and - 40°C ≤ TA ≤ 85°C. All voltages are referenced to VIN unless
otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
t UVAL
—
1.0
—
ms
t OVAL
—
1.0
—
ms
t DISAL
—
1.0
—
ms
Short Circuit Protection Delay
t SCPD
—
—
10
µs
Overcurrent Limit Filter Time
t OCFT
—
100
—
µs
t OC
—
3.0
—
ms
Default
—
1.0
—
Adjustable with an External Capacitor
1.0
—
—
10
28
46
130
200
270
Maximum with External Resistor
—
1000
—
Minimum with External Resistor
—
100
—
UNDERVOLTAGE CONTROL
UV Active to Gate Low Filter Time
OVERVOLTAGE CONTROL
OV Active to Gate Low Filter Time
DISABLE INPUT CONTROL PIN (DISABLE) (14)
DISABLE Active to Gate Low Filter Time
CURRENT LIMIT CONTROL PINS (ILIM, ICHG)
Overcurrent Limit Regulation Time
ICHG Rise Time
t ICHGR
ms
POWER GOOD OUTPUT PINS (PG, PG) (15)
Power Good Output Delay Time, from Power MOSFET Enhancement to PG
and PG Asserted
t PG
ms
START-UP AND RETRY DELAY TIMER (TIMER)
Start-Up and Retry Delay Timer
Default
t TIMER
ms
Notes
14. Referenced to VPWR.
15. Referenced to VIN.
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Analog Integrated Circuit Device Data
Freescale Semiconductor
9
FUNCTIONAL DESCRIPTION
INTRODUCTION
FUNCTIONAL DESCRIPTION
INTRODUCTION
Most telecom and data transfer networks require that
circuit boards be inserted and removed from the system
without powering down the entire system. When a circuit
board is inserted into or removed from a live backplane, the
filter or bypass capacitors at the input of the board’s power
module or switching power supply can cause large transient
currents when being charged or discharged. These currents
can cause severe and permanent damage to the boards, thus
making the system unstable. Figure 4 displays the inrush
current to the filter capacitor if a hot swap device is absent.
The inrush current reached an unsafe value of more than
55 A.
voltages in a controlled manner and regulating the inrush
current to a user-programmable limit, thus allowing the
system to safely stabilize (see Figure 5). The 34652 provides
protection against overcurrent, undervoltage, overvoltage,
and overtemperature. Furthermore, it protects the system
from short circuits.
Figure 5. Circuit Board Insertion With the Hot Swap
Device, Inrush Current Limited
Figure 4. Circuit Board Insertion Without a
Hot Swap Device, Inrush Current Not Limited
The 34652 is an integrated negative voltage hot swap
controller with an internal Power MOSFET. The 34652
resides on the plug-in boards and allows the boards to be
safely inserted or removed by powering up the supply
By integrating the control circuitry and the Power MOSFET
switch into a space-efficient package, the 34652 offers a
complete, cost-effective, and simple solution that takes much
less board space than a similar part with an external Power
MOSFET requires.
The 34652 can be used in - 48 V telecom and networking
systems, servers, electronic circuit breakers, - 48 V
distributed power systems, negative power supply control,
and central office switching.
FUNCTIONAL PIN DESCRIPTION
NEGATIVE SUPPLY INPUT VOLTAGE (VIN)
The VIN pin is the most negative power supply input. All
pins except the DISABLE pin are referenced to this input.
POWER GOOD OUTPUT (ACTIVE HIGH) (PG)
The PG pin is the active high power good output signal that
is used to enable or disable a load. This signal goes active
after a successful power-up sequence and stays active as
long as the device is in normal operation and is not
experiencing any faults.
The signal is deactivated under the following conditions:
• Power is turned off.
• The device is disabled for more than 1.0 ms.
• The device exceeded its thermal shutdown threshold for
more than 12 µs.
• The device is in overvoltage or undervoltage mode for
more than 1.0 ms.
• Load current exceeded the overcurrent limit for more than
3.0 ms.
This pin is referenced to VIN.
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Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DESCRIPTION
FUNCTIONAL PIN DESCRIPTION
POWER GOOD OUTPUT (ACTIVE LOW) (PG)
UNDERVOLTAGE CONTROL (UV)
The PG pin is the active low power good output signal that
is used to enable or disable a load. This signal goes active
after a successful power-up sequence and stays active as
long as the device is in normal operation and is not
experiencing any faults.
The signal is deactivated under the following conditions:
The UV pin is used to set the lower limit of the input voltage
operation range. If the UV pin voltage goes below the
undervoltage threshold value, the device turns off the internal
Power MOSFET and deactivates the two power good
outputs, PG and PG. The Power MOSFET stays off until the
UV rises above the threshold value. The undervoltage
detection circuit has a 1.0 ms filter timer.
The UV pin can be left unconnected for the typical default
threshold value of 37 V or the user can set the threshold
value externally with a simple voltage divider using resistors
between the VPWR and VIN pins.
• Power is turned off.
• The device is disabled for more than 1.0 ms.
• The device exceeded its thermal shutdown threshold for
more than 12 µs.
• The device is in overvoltage or undervoltage mode for
more than 1.0 ms.
• Load current exceeded the overcurrent limit for more than
3.0 ms.
This pin is referenced to VIN.
OUTPUT VOLTAGE (VOUT)
The VOUT pin is the drain of the internal Power MOSFET
and supplies a current-limited voltage to the load. The load
connects between the VOUT and VPWR pins.
START-UP AND RETRY DELAY TIMER (TIMER)
This input is used to control the time-base used to
generate the timing sequences at start-up and the retry delay
when the device experiences any fault. The TIMER pin can
be left unconnected for a default timer value of 200 ms or the
user can connect a resistor between this pin and the VIN pin
to set the timer value externally. The timer value can vary
between 100 ms and 1000 ms.
OVERVOLTAGE CONTROL (OV)
The OV pin is used to set the upper limit of the input
voltage operation range. If the OV pin voltage goes above the
overvoltage threshold value, the device turns off the internal
Power MOSFET and deactivates the two power good
outputs, PG and PG. The Power MOSFET stays off until the
OV drops below the threshold value. The overvoltage
detection circuit has a 1.0 ms filter timer.
The OV pin can be left unconnected for the typical default
threshold value of 78 V or the user can set the threshold
value externally with a simple voltage divider using resistors
between the VPWR and VIN pins.
POSITIVE SUPPLY VOLTAGE INPUT (VPWR)
The VPWR pin is the most-positive power supply input.
The load connects between the VPWR and VOUT pins.
DISABLE INPUT CONTROL (DISABLE)
The DISABLE pin is used to easily disconnect or connect
the load from the main power line by disabling or enabling the
34652. It can also be used to reset the fault conditions that
cause a “Power No Good” signal.
If left open or connected to VPWR, the DISABLE pin is
inactive and the device is enabled. If a positive voltage
(above VPWR) or a negative voltage (below VPWR) is applied
to DISABLE, it is active and the device is disabled. The
disable function has a 1.0 ms filter timer.
This pin is referenced to VPWR.
CURRENT LIMIT CONTROL (ILIM)
The ILIM pin is used to set the overcurrent limit during
normal operation. This pin can be left unconnected for a
default overcurrent limit value of 1.0 A or the user can
connect an external resistor between the ILIM and VIN pins
to set the overcurrent limit value. This value can vary
between 0.35 A and 2.25 A. The overcurrent detection circuit
has a 100 µs filter timer.
CHARGING CURRENT LIMIT CONTROL (ICHG)
The ICHG pin is used to set the current limit that is used to
charge the load’s input capacitor, hence limiting the inrush
current to a known constant value. This pin can be left
unconnected for a default charging current limit value of 0.1 A
and a default ICHG rise time of 1.0 ms. Or the user can
connect an external resistor between the ICHG and VIN pins
to set the current limit value between 0.05 A and 0.5 A and an
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
11
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
START-UP SEQUENCE
When power is first applied to the 34652 by connecting the
VIN pin to the negative voltage rail and the VPWR pin to the
positive voltage rail, the 34652 keeps the Power MOSFET
turned off, deactivates the power good output signals, and
resets the retry counter. If the device is disabled, no further
activities will occur and power-up would not start. If the device
is enabled, it starts to establish an internally regulated supply
voltage required for the internal circuitry. The Power
MOSFET will stay off until the start of the charging process.
After Power-ON Reset (POR) and once the Undervoltage
Lockout (UVLO) threshold is cleared, the 34652 checks for
external components on four pins — the UV, the ILIM , the
ICHG , and 128 µs later the OV — to set the levels of the
Undervoltage Threshold, the Overcurrent Limit, the Charging
Current Limit, and the Overvoltage Threshold, respectively.
The device also checks for external components on the
TIMER pin to decide on the Start-Up and Retry Delay Timer
value, and the device keeps checking the TIMER pin
continuously throughout the operation.
The device then initiates the start-up timer (Point A in
Figure 6) and checks for the start-up conditions (see next
paragraph). The duration of the timer is either a default or a
user-programmable value. For undervoltage and overvoltage
faults during power up the 34652 retries infinitely until normal
input voltage is attained. If the die temperature ever
increased beyond the thermal shutdown threshold or the
device is disabled, then the start-up timer resets and the retry
counter increments. If after 10 retries the die temperature is
still high and the device is still disabled, the 34652 will not
retry again and the power in the device must be recycled or
the device must be disabled to reset the retry counter.
Figure 6. Start-Up Sequence
Start-Up Conditions
The start-up conditions are as follows:
• Input voltage is below the overvoltage turn-off threshold.
This threshold is either a default or user-programmable
value.
• Input voltage is above the undervoltage turn-off threshold.
This threshold is either a default or user-programmable
value.
• Die temperature is less than thermal shutdown
temperature.
• Device is enabled.
If the start-up conditions are satisfied for a time equal to
the length of the start-up timer and the retry counter is less
than or equal to 10, the device starts to turn on the Power
MOSFET gradually to control the inrush current that charges
up the load capacitor to eventually switch on the load (Point B
in Figure 6).
Charging Process
When charging a capacitor from a fixed voltage source, a
definite amount of energy will be dissipated in the control
circuit, no matter what the control algorithm is. This energy is
equal to the energy transferred to the capacitor — ½ CV 2.
With this in mind, the Power MOSFET in the 34652 cannot
absorb this pulse of energy instantaneously, so the pulse
must be dissipated over time. To limit the peak power
dissipation in the Power MOSFET and to spread out the
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Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
NORMAL MODE
If one of the start-up conditions (list on page 12) is violated
any time from the start of the Power MOSFET enhancement
process and thereafter during normal operation, the Power
MOSFET turns off and the power good output signals
deactivate, disabling the load, and a new timer cycle starts as
explained previously. The 34652 also monitors the load
current to prevent any overload or short circuit conditions
from happening in order to protect the load from damage.
LOAD CURRENT CONTROL
When in normal operation mode, the 34652 monitors the
load and provides two modes of current control as explained
in the paragraphs below.
Overcurrent Mode
Figure 7. Power MOSFET Turn-On and the Gradual
Increase in the Charging Current from 0 A to ICHG
(2.0 ms in Example)
The ICHG current charges up the load capacitor relatively
slowly. When the load capacitor is fully charged, the Power
MOSFET reaches its full enhancement, which triggers the
current limit detection to change from ICHG to ILIM and the load
current to decrease (Point C in Figure 6, page 12). The
current spike at Point C in Figure 6 is better displayed in
Figure 8. We can see that when the ⎜VOUT - VIN ⎜< 0.5 V, the
Power MOSFET fully turns on to reach its full enhancement,
charging the capacitor an additional 0.5 V with a higher
current value that quickly ramps down. This eliminates the
need for a current slew rate control because the hazard for a
voltage change is less than 0.5 V. The power good output
signals activate after a 20 ms delay (Point D in Figure 6),
which in turn enables the load. The 34652 is now in normal
operation mode and the retry counter resets.
The 34652 monitors the load for overcurrent conditions. If
the current going through the load becomes larger than the
overcurrent limit for longer than the overcurrent limit filter
timer of 100 µs, the overcurrent signal is asserted and the
gate of the Power MOSFET is discharged to try to regulate
the current at the ILIM value (Point A in Figure 9). The 34652
is in overcurrent mode for 3.0 ms. If after a 3.0 ms filter timer
the device is still in overcurrent mode, the device turns off the
Power MOSFET and deactivates the power good output
signals (Point B in Figure 9). The 34652 then initiates another
start-up timer and goes back through the enhancement
process. If during the 3.0 ms timer the fault was cleared, then
the 34652 goes back to the normal operation mode and the
power good output signals stay activated as shown in
Figure 10, page 14. This way the device overcomes
temporary overcurrent situations and at the same time
protects the load from a more severe overcurrent situation.
Figure 9. Overcurrent Mode for More Than 3.0 ms
Figure 8. Full Power MOSFET Turn-On and Current
Spike Associated with It. End of Charging Process
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
13
FUNCTIONAL DEVICE OPERATION
OPERATIONAL MODES
Figure 10. Overcurrent Mode for Less Than 3.0 ms
Short Circuit Mode
If the current going through the load becomes > 5.0 A, the
Power MOSFET is discharged very fast (in less than 10 µs)
to try to regulate the current at the ILIM value, and the 34652
is in the overcurrent mode for 3.0 ms. Then it follows the
pattern outlined in the Overcurrent Mode paragraph above.
Figure 11. Disabling and Enabling the 34652
Figure 12 demonstrates that the 34652 must be enabled
for the length of the start-up timer to start turning on the
Power MOSFET. After the fourth disable signal, the 34652
was enabled for the length of the start-up timer. And because
the retry counter is less than 10, the 34652 turns on the
Power MOSFET and starts the charging process (refer to the
Charging Process section, pages 12–13).
DISABLING AND ENABLING THE 34652
When a negative voltage (< 1.8 V below VPWR) is applied
to the DISABLE pin for more than 1.0 ms (Point A in
Figure 11), the 34652 is disabled, the Power MOSFET turns
off, and the power good output signals deactivate. The 34652
stays in this state until the voltage on the DISABLE pin is
brought to within ± 1.2 V of VPWR for more than 1.0 ms to
enable the device (Point B in Figure 11). Then a new start-up
sequence initiates as described on page 12. Applying a
positive voltage (> 1.8 V above VPWR) would also disable the
34652 in the same manner.
Figure 12. Start-Up Timer Versus Disable
34652
14
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
PROTECTION FEATURES
BOARD REMOVAL
34652 STATE MACHINE DIAGRAM
When the board is removed, its power ramps down. As
soon as the 34652’s input voltage reaches the undervoltage
turn-off threshold, the undervoltage detection circuit activates
and the Power MOSFET turns off for having violated one of
the start-up conditions (list on page 12).
Figure 13 is a representation of the 34652 behavior in
different modes of operation.
Temp > 160°C
Filter = 12 µs
Temp < 135°C
Filter = 12 µs
Thermal
Shutdown
MOSFET → OFF
PG = 0
VPWR > VOV(OFF)
Filter = 1.0 ms
Start-Up Conditions
VPWR < VOV(ON)
Filter = 1.0 ms
Overvoltage
MOSFET → OFF
PG = 0
VPWR < VUV(OFF)
Filter = 1.0 ms
VPWR > VUV(ON)
Filter = 1.0 ms
Undervoltage
MOSFET → OFF
PG = 0
• Thermal Shutdown < 160°C
• DISABLE = 0
N=N+1
• VPWR < VOV(OFF)
• VPWR > VUV(OFF)
Filter = t TIMER
N > 10
N ≤ 10
Charging Mode
Fail PG
Check
Retry Fault
STOP
Pass PG
Check
Toggle DISABLE
or cycle Power Off
then On to clear fault
Power Off
MOSFET → OFF
PG = 0
N=0
POR is generated
VPWR < VUVLOF
Filter = 1.0 ms
Power
Good Check
If ILOAD < ILIM
and VDS < 500 mV
for 20 ms
Overcurrent
for > 3.0 ms
ILOAD > ILIM
for 100 µs
Normal Operation
Overcurrent Mode
PG = 1
Filter = 3.0 ms
N=0
ILOAD < ILIM - ILIMHY
Ext. Resistor Check
A signal “set” is generated to check
resistors on UV, ILIM, ICHG, and
TIMER pins and 128 µs later
the OV pin
VPWR > VUVLOR
Filter = 1.0 ms
VDS < 500 mV
Turn Off
MOSFET → OFF
PG = 0
ILOAD > ISHORT
DISABLE = 0
Filter = 1.0 ms
Short Circuit
Detection
Fast Gate Discharge
< 10 µs
DISABLE
MOSFET → OFF
PG = 0
N=0
POR is generated
DISABLE = 1
Filter = 1.0 ms
Figure 13. State Diagram
PROTECTION FEATURES
UNDERVOLTAGE
When the voltage on the UV pin drops below the
undervoltage falling threshold for more than 1.0 ms, an
undervoltage fault is detected and one of the start-up
conditions (list on page 12) is violated. The 34652 turns off
the Power MOSFET and deactivates the power good output
signals, disabling the load (Point A in Figure 14). The 34652
stays in this state until the voltage on the UV pin rises above
the undervoltage rising threshold for more than 1.0 ms,
signaling that the supply voltage is in the normal operation
range (Point B in Figure 14). Then a new start-up sequence
initiates as described on page 12. The undervoltage
detection circuit is also equipped with a 1.0 V hysteresis
when in default mode. The hysteresis value depends on the
undervoltage detection threshold and can be calculated as
follows:
VUVHY = VUV (RISING) * [1 - (1.3 V - VUVCHY) / 1.3 V ]
Figure 14. Undervoltage Fault Followed by a
New Start-Up Sequence
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
15
FUNCTIONAL DEVICE OPERATION
PROTECTION FEATURES
Figure 15 shows how the 34652 uses the start-up timer to
make sure that the input voltage is above the undervoltage
falling threshold. The 34652 was in normal operation before
Point A. At Point A an undervoltage fault occurs. Then the
fault is cleared at Point B, and the 34652 initiates a start-up
sequence. Before the end of the start-up timer another
undervoltage fault occurs at Point C, so the 34652 does not
turn on the Power MOSFET. At Point D the fault is cleared
again for the length of the start-up timer. The 34652 turns on
the Power MOSFET and starts the charging process (refer to
Charging Process, pages 12–13).
Figure 16. Overvoltage Fault
THERMAL SHUTDOWN
Figure 15. Start-Up Timer Protection Against
Undervoltage Faults
OVERVOLTAGE
When the voltage on the OV pin exceeds the overvoltage
rising threshold for more than 1.0 ms, an overvoltage fault is
detected and one of the start-up conditions (list on page 12)
is violated. The 34652 turns off the Power MOSFET and
deactivates the power good output signals, thus disabling the
load. The 34652 stays in this state until the voltage on the OV
pin falls below the overvoltage falling threshold for more than
1.0 ms, signaling that the supply voltage is in the normal
operation range. Then a new start-up sequence initiates as
described on page 12.
The overvoltage detection circuit is also equipped with a
2.0 V hysteresis when in default mode. The hysteresis value
depends on the overvoltage detection threshold and can be
calculated as follows:
VOVHY = VOV (RISING) * [1 - (1.3 V - VOVCHY) / 1.3 V ]
The waveforms for an overvoltage fault are shown in
Figure 16, page 16.
The thermal shutdown feature helps protect the internal
Power MOSFET and circuitry from excessive temperatures.
During start-up and thereafter during normal operation, the
34652 monitors the temperature of the internal circuitry for
excessive heat. If the temperature of the device exceeds the
thermal shutdown temperature of 160°C, one of the start-up
conditions (list on page 12) is violated, and the device turns
off the Power MOSFET and deactivates the power good
output signals. Until the temperature of the device goes
below 135°C, a new start-up sequence will not be initiated.
This feature is an advantage over solutions with an external
Power MOSFET, because it is not easy for a device with an
external MOSFET to sense the temperature quickly and
accurately. The thermal shutdown circuit is equipped with a
12 µs filter.
Thermal design is critical to proper operation of the 34652.
The typical RDS(ON) of the internal Power MOSFET is
0.144 Ω at room ambient temperature and can reach up to
0.251 Ω at high temperatures. The thermal performance of
the 34652 can vary depending on many factors, among them:
• The ambient operating temperature (TA).
• The type of PC board—whether it is single layer or multilayer, has heat sinks or not, etc.—all of which affects the
value of the junction-to-ambient thermal resistance (RθJA).
• The value of the desired load current (ILOAD).
When choosing an overcurrent limit, certain guidelines
need to be followed to make sure that if the load current is
running close to the overcurrent limit the 34652 does not go
into thermal shutdown. It is good practice to set the
parameters so that the resulting maximum junction
temperature is below the thermal shutdown temperature by a
safe margin.
Equation 1, on the following page can be used to calculate
the maximum allowable overcurrent limit based on the
maximum desired junction temperature or vice versa.
34652
16
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATION
PROTECTION FEATURES
The power dissipation in the device can be calculated as
follows:
P = I2(LOAD) * RDS(ON)
OR
P = [TJ(max) - TA(max)] / RθJA
Combining the two equations:
I2(LOAD) = [ TJ (max) - TA(max)] / [RθJA * RDS(ON)] Eq 1
For example:
For example:
ICHG = 100 mA, the default value
CLOAD = 400 µF, a very large capacitor
VPWR = 80 V, worst case
Then:
The power pulse magnitude = ICHG * VPWR = 8.0 W
The power pulse duration = CLOAD * VPWR / ICHG = 320 ms
Figure 17 displays the temperature profile of the device
under the instantaneous power pulse during the charging
process. Table 5 depicts thermal resistance values for
different board configurations.
TA(max) = 55°C
RθJA = 51°C/W for a four-layer board
RDS(ON) = 0.251 Ω at high temperatures
Then:
I2(LOAD) = [ TJ (max) - 55°C] / [51°C/W * 0.251 Ω]
I2(LOAD) = [ TJ (max) - 55°C] / 12.80°C / A2
60.0
So if the overcurrent limit is 2.0 A, then the maximum
junction temperature is 106.2°C, which is well below the
thermal shutdown temperature that is allowed.
The previous explanation applies to steady state power
when the device is in normal operation. During the charging
process, the power is dominated by the I * V across the Power
MOSFET. When charging starts, the power in the Power
MOSFET rises up and reaches a maximum value of I * V, then
quickly ramps back down to the steady state level in a period
governed by the size of the load’s input capacitor that is being
charged and by the value of the charging current limit ICHG.
In this case the instantaneous power dissipation is much
higher than the steady state case, but it is on for a very short
time.
Temperature
Rise
(°C)
Temperature
Rise
50.0
40.0
30.0
20.0
10.0
0.0
0
100
200
300
400
TimTime
e (m(ms)
illisec)
Figure 17. Instantaneous Temperature Rise of an 8.0 W
Table 5. Thermal Resistance Data
Type
Condition
Symbol
Value
Unit
Junction to Ambient
Single-layer board (1s), per JEDEC JESD51-2 with board (JESD51-3) horizontal
RθJA
103
°C/W
Junction to Ambient
Four-layer board (2s2p), per JEDEC JESD51-2 with board (JESD51-3) horizontal
RθJMA
65
°C/W
Junction to Ambient
Single-layer board with a 300 mm2 radiator pad on its top surface, not standard JEDEC
—
69
°C/W
2
Junction to Ambient
Single-layer board with a 600 mm radiator pad on its top surface, not standard JEDEC
—
65
°C/W
Junction to Ambient
Four-layer board with a via for each thermal lead, not standard JEDEC
—
51
°C/W
2
Junction to Ambient
Four-layer board with a 300 mm radiator pad on its top surface and a full array of vias
between radiator pad and top surface, not standard JEDEC
—
47
°C/W
Junction to Ambient
Four-layer board with a 600 mm2 radiator pad on its top surface and a full array of vias
between radiator pad and top surface, not standard JEDEC
—
47
°C/W
Junction to Board
Thermal resistance between die and board per JEDEC JESD51-8
RθJB
29
°C/W
Junction to Case
Thermal resistance between die and case top
RθJC
33
°C/W
Temperature difference between package top and junction per JEDEC JESD51-2
ΨJT
12
°C/W
Thermal resistance between junction and thermal lead, not standard JEDEC
RθJL
33
°C/W
Junction to Package
Top
Junction to Lead
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
17
TYPICAL APPLICATIONS
TYPICAL APPLICATIONS
GND
Live Backplane
UV VPWR
DISABLE
44 kΩ
PG
PG
OV
VOUT (2)
VIN (4)
TIMER
ICHG
ILIM
33652
R1
44 kΩ
UV VPWR
R2
DISABLE
PG
Enable/Enable
OV
ILIM
DC/DC
Converter
RILIM
ICHG
RICHG
TIMER
CLOAD
VOUT (2)
VIN (4)
CICHG
R3
RTIMER
-48 V
Application
Dependent
PG
Figure 19. Typical Application Diagram with External
Components Necessary to Program the Device
UNDERVOLTAGE AND OVERVOLTAGE
DETECTION
PLUG-IN CARD
33652
PLUG-IN CARD
GND
Live Backplane
The 34652 resides on the plug-in board (see Figures 18
and 19), allowing the board to be safely inserted or removed
without damaging electrical equipment. The 34652 can be
operated with no external components other than the power
good output signal pull-up resistor if the default mode was
selected for all the programmable features. This is one of the
great advantages of the 34652: it operates with minimal user
interface and minimal external component count and still
offers complete hot swapping functionality with all the
necessary protection features, from undervoltage/
overvoltage detection, to current limiting, to short circuit
protection and power good output signaling. The default
values were chosen to be sufficient for many standard
applications.
Figure 18 is a typical application diagram depicting the
default mode and using the power good output signal pull-up
resistor. Refer to the static and dynamic electrical
characteristics tables on pages 6 through 9 for the various
default values.
Application
Dependent
Enable/Enable
CLOAD
DC/DC
Converter
-48 V
Figure 18. Typical Application Diagram with Default
Settings and Minimal External Components
The 34652 can be also programmed for different values of
the Overcurrent Limit, the Charging Current Limit, the StartUp and Retry Delay Timer, and the UV / OV detection
thresholds using external components connected to the
device. Figure 19 shows the 34652 with the required external
components that allow access to all programmable features
in the device.
The UV and OV pins are used to monitor the input voltage
to ensure that it is within the operating range and that there
are no overvoltage or undervoltage conditions, and to quickly
turn off the Power MOSFET if there are. The pins are
connected to internal comparators that compare the voltages
at the UV and OV pins with a reference voltage. The UV and
OV pins can be left unconnected for the default threshold
values of their trip point or the user can set the threshold
values externally with a simple voltage divider using resistors
between VPWR and VIN (resistors R1, R2, and R3 in
Figure 19). For the default mode, the 34652 is equipped with
an internal resistor divider that acts the same as the external
one. The typical default values of 37 V for the UV turn-off
threshold (falling threshold) and 78 V for the OV turn-off
threshold (rising threshold) will give a typical operating range
of 38 V to 76 V. This range is suitable for telecom industry
standards.
When the device passes the UVLO threshold, it checks if
there is any external resistor divider connected to the OV and
UV pins. If there is, it determines the value of the UV/OV
thresholds accordingly. If there is not, it defaults to the
internal resistor divider. It then uses the UV/OV detection
circuits to check the input supply levels before turning on the
Power MOSFET during the Start-Up Timer delay and
thereafter. As long as the voltage on the UV pin is above its
falling threshold and the voltage on the OV pin is below its
rising threshold, the supply is within operating range and the
Power MOSFET is allowed to turn on and stay on. If the UV
pin drops below its falling threshold or the OV pin rises above
its rising threshold, then one of the start-up conditions (refer
to page 12 for list) is violated and the Power MOSFET turns
off, the power good signals deactivate, and a new start-up
34652
18
Analog Integrated Circuit Device Data
Freescale Semiconductor
TYPICAL APPLICATIONS
timer initiates. The UV and OV detection circuits are
equipped with a 1.0 ms filter to filter out momentary input
supply dips. Filter capacitors between the UV and VIN pins
and between the OV and VIN pins could also be added to
adjust the UV/OV filter time and prevent more transients from
affecting the device’s operation, especially if the input supply
has a lot of noise.
If the three-resistor divider, which is the recommended
approach, could not produce acceptable resistor values, the
user can consider two separate resistor dividers, one divider
for each pin from VPWR to VIN. An advantage of the tworesistor dividers approach is that the user can set the trip
points of the UV and OV thresholds independently.
TIMER
Guidelines for Choosing Resistor Divider Values
The total current flowing in the resistors is equal to the
supply voltage divided by the total series resistance. The
supply voltage can reach up to 80 V and the device will still
be in normal operation, the resistors connected and drawing
current. So the resistor values should be chosen high enough
to allow for a reasonable current to pass through them and
not dissipate a lot of power or cause input noise that would
trip the UV / OV detection circuit.
Another consideration is whether or not the values of the
resistors are readily available. The tolerance of the resistors
should be 1% or better to get an accurate reading.
Note Accuracy requirements are application dependent.
To demonstrate the importance of the accuracy of the
resistors, let’s look at a system with an operating range of
40 V for UV falling to 75 V for OV rising as an example. This
operating range will be scaled down for the device’s internal
circuitry to operate the UV/OV detection circuits. The scale
factor is 31.6 for UV and 57.1 for the OV. Taking overvoltage
as an example, this means that every 5.0 mV change on the
OV pin represents a 0.29 V change for the OV trip point on
the supply. Which says that an error of 5.0 mV due to the
resistors not being accurate will result in an error of 0.29 V for
the trip point, and depending on how close we are operating
to the OV rising threshold the device might detect an OV
condition and turn off the Power MOSFET prematurely. The
same argument applies to the UV pin.
Example of Calculations for Resistor Values
The following equations are examples of calculating
resistor values using the same operating range as in the
previous paragraph:
R3 = 1.3 * R1 * VUV (RISING) / (VOV (RISING) (VUV (RISING) - 1.3))
R2 = R3 (VOV (RISING) / VUV (RISING) - 1)
The TIMER pin on the 34652 gives the user control over
the time base used to generate the timing sequences at startup. The same timer controls the retry delay when the device
experiences any fault. The TIMER pin can be left
unconnected for a default timer value of 200 ms or the user
can connect an external resistor (RTIMER) between the
TIMER and VIN pins, as shown in Figure 19, page 18, to set
the timer value externally.
After the device passes the UVLO threshold and
continuously after that, the 34652 checks the TIMER pin for
any external components to determine the value of the timer.
During start-up and if any fault occurred, this timer value is
used when initiating a start-up sequence.
Choosing the External Resistor RTIMER Value
The user can change the value of the Start-Up Delay
Timer (t TIMER) by adding a resistor (RTIMER) between the
TIMER and VIN pins, as shown in Figure 19, page 18. The
timer value ranges between 100 ms and 1000 ms, with a
default value of 200 ms. Table 6 lists examples of RTIMER for
different values of the t TIMER and Figure 20, page 20, shows
a plot of RTIMER versus t TIMER . It is recommended that the
closest 1% standard resistor value to the actual value be
chosen.
Note Accuracy requirements are application dependent.
To calculate the value of the RTIMER resistor we use the
following equations:
t TIMER (ms) = 20 (ms) + 2.0 * [RTIMER (kΩ) + 1.0 kΩ]
RTIMER (kΩ) = [t TIMER (ms) - 20 (ms) ] / 2.0 - 1.0 kΩ
Table 6. RTIMER Values for Some Desired t TIMER Values
t TIMER (ms)
RTIMER (kΩ)
t TIMER (ms)
RTIMER (kΩ)
100
39
600
289
150
64
650
314
200
89
700
339
250
114
750
364
300
139
800
389
350
164
850
414
400
189
900
439
and the closest 1% standard resistor value is 8.66 kΩ.
Now, from the second equations we can solve for R2:
450
214
950
464
500
239
1000
489
R2 = 7.18 kΩ
and the closest 1% standard resistor value is 7.15 kΩ.
500
264
—
—
Where VOV (RISING) = 75 V and VUV (RISING) = 41 V
Note Some iteration may be required to get the right
values and also standard resistor values. The recommended
maximum value of the series resistance between the UV/OV
pins and VPWR pin is 500 kΩ.
Here we have two equations and three unknowns. If we
select a value for R1 of 487 kΩ, then from the first equation:
R3 = 8.72 kΩ
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
19
TYPICAL APPLICATIONS
DISABLING AND ENABLING THE 34652
550
The Disable control input (DISABLE) provides two
functions:
500
RTIMER(kohm)r
(kΩ)
Rtimer
450
• External enable/disable control.
• Manual resetting of the device and the retry counter after
a fault has occurred.
400
350
300
250
200
150
100
50
0
0
200
400
600
800
1000
1200
t TIMER (ms)
ttim er (m s)
Figure 20. External Resistor (RTIMER) Value Versus
Start-Up and Retry Delay Timer Value (t TIMER)
POWER GOOD OUTPUT SIGNALS
The power good pins PG and PG are output pins that are
used to directly enable a power module load. The device has
active high and active low power good output signals.
Choosing which power good active signal depends on the
Enable signal requirement of the load. This feature allows the
34652 to adapt to different applications and a wide variety of
loads.
The power good output signal is active if the Power
MOSFET is fully enhanced and the device is in normal
operation. The signal goes active after a typical 20 ms delay.
The signal deactivates if one of the following occurs:
• Power is turned off.
• The device is disabled for more than 1.0 ms.
• The device exceeded its thermal shutdown threshold for
more than 12 µs.
• The device is in overvoltage or undervoltage mode for
more than 1.0 ms.
• Load current exceeded the overcurrent limit for more than
3.0 ms.
When the power good output signal becomes inactive, it
disables the load, protecting it from any faults or damage.
These loads are usually DC/ DC converters, depicted in
Figure 19, page 18. An LED can also be connected to PG to
indicate that the power is good.
The PG and PG pins are referenced to VIN and require a
pull-up resistor connected to VPWR (Figures 18 and 19,
page 18).
Using the DISABLE pin, a user can enable /disable the 34652
device, which facilitates easy access to connect the load to or
disconnect it from the main power rail.
When power is first applied, the DISABLE pin must be
inactive in order for the 34652 to initiate a start-up sequence.
If the DISABLE pin is active, the device makes no further
steps until the pin is inactive. If the DISABLE pin is activated
at any point during the start-up and thereafter during normal
operation, then the retry counter resets, the Power MOSFET
turns off, and the power good output signals deactivate. The
DISABLE circuit is equipped with a 1.0 ms filter to filter out
any glitches or transients on the DISABLE input and prevent
the Power MOSFET from turning off prematurely.
The DISABLE pin is referenced to VPWR . If left open or
connected to VPWR, meaning the voltage at the DISABLE
pin is between VPWR + 1.2 V and VPWR - 1.2 V, it is inactive
and the device is enabled. If a positive voltage (1.8 V above
VPWR) or a negative voltage (1.8 V below VPWR) is applied to
DISABLE, it is active and the device is disabled.
CHARGING CURRENT LIMIT
When the device passes the UVLO threshold, it checks if
there is any external resistor or external capacitor connected
to the ICHG pin. If there is, then it determines the value of the
charging current limit value and the charging current limit rise
time accordingly. If there is not, it uses the default charging
current limit value of 100 mA and rise time of 1.0 ms.
Note Users are allowed to connect an external capacitor
to the ICHG pin only if an external resistor is also connected.
During the external components’ check, a capacitor produces
an impulse of current and an external resistor will be
detected, even it the external resistor is absent.
When the Power MOSFET is turned on, the current limit is
set gradually from 0 A to ICHG. This current charges up the
load capacitor relatively slowly. When the load capacitor is
fully charged, the Power MOSFET reaches its full
enhancement, which triggers the current limit to change from
ICHG to ILIM and the load current to decrease. The power good
output signals activate after a 20 ms delay, which in turn
enables the load. The 34652 is now in normal operation
mode and the retry counter resets.
34652
20
Analog Integrated Circuit Device Data
Freescale Semiconductor
TYPICAL APPLICATIONS
Choosing the External Resistor RICHG Value
The user can change the value of the charging current limit
by adding a resistor (RICHG) between the ICHG and VIN pins,
as shown in Figure 19, page 18. The charging current value
ranges between 50 mA and 500 mA, with a default value of
100 mA. Table 7 lists examples of RICHG for different values
of ICHG and Figure 21 shows a plot of RICHG versus ICHG . It is
recommended that the closest 1% standard resistor value to
the actual value be chosen.
Note Accuracy requirements are application dependent.
To calculate the value of the RICHG resistor we use the
following equations:
ICHG (A) = [ RICHG (kΩ) + 1.4 kΩ] / 335
RICHG (kΩ) = 335 * ICHG (A) - 1.4 kΩ
Table 7. RICHG Values for Some Desired ICHG Values
ICHG (A)
RICHG (kΩ)
0.05
15.35
0.1
32.10
0.15
48.85
0.2
65.60
0.25
82.35
0.3
99.10
0.35
115.85
0.4
135.60
0.45
149.35
0.5
166.10
180
160
140
RICHG (kohm)
(kΩ)
RICHG
The low charging current value of ICHG is intended to limit
the temperature increase during the load capacitor charging
process, and the gradual rise to ICHG is to prevent transient
dips in the input voltage due to sharp increases in the limit
current. This prevents the input voltage from drooping due to
current steps acting on the input line inductance, and that in
turn prevents a premature activation of the UV detection
circuit.
120
100
80
60
40
20
0
0
0.1
0.2
0.3
IICHG
CHG (A)
0.4
0.5
0.6
Figure 21. External Resistor (RICHG ) Value Versus
Charging Current Limit Value (ICHG)
Choosing the External Capacitor CICHG Value
The user can also change the charging current rise time by
adding a capacitor (CICHG) between the ICHG and VIN pins,
as shown in Figure 19, page 18. The charging current rise
time ranges between 1.0 ms (default value) and a
recommended maximum of 10 ms. Table 8 lists examples of
CICHG for different values of t ICHGR and Figure 22 shows a
plot of CICHG versus t ICHGR.
To calculate the value of the CICHG capacitor we use the
following equation:
CICHG(nF) = 1000 * t ICHGR(ms) / [ 3 * RICHG(kΩ) ]
Table 8. CICHG Values for Some Desired t ICHGR Values
at a Specific ICHG Value
t ICHGR (ms)
CICHG (nF)
ICHG = 0.05 A
CICHG (nF)
ICHG = 0.1 A
CICHG (nF)
ICHG = 0.5 A
1.0
21.72
10.38
2.01
2.0
43.43
20.77
4.01
3.0
65.15
31.15
6.02
4.0
86.86
41.54
8.03
5.0
108.58
51.92
10.03
6.0
130.29
62.31
12.04
7.0
152.01
72.69
14.05
8.0
173.72
83.07
16.05
9.0
195.44
93.46
18.06
10
217.16
103.84
20.07
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
21
TYPICAL APPLICATIONS
to different requirements and operating environments. The
overcurrent value ranges between 0.35 A and 2.25 A, with a
default value of 1.0 A. Table 9 lists examples of RILIM for
different values of ILIM and Figure 23 shows a plot of RILIM
versus ILIM. It is recommended that the closest 1% standard
resistor value to the actual value be chosen.
Note Accuracy requirements are application dependent.
To calculate the value of the RILIM resistor we use the
following equations:
220
200
ICHG
ICHG = 0.05 A
180
C ICHG (nF)
CICHG
(nF)
160
140
120
100
ILIM (A) = 129 / [ RILIM (kΩ) + 1.4 kΩ ]
ICHG
ICHG = 0.1 A
80
RILIM (kΩ) = [ 129 / ILIM (A)] - 1.4 kΩ
60
40
Table 9. RILIM Values for Some Desired ILIM Values
ICHG
ICHG = 0.5 A
20
0
0
1
2
3
4
5
6
7
8
9
ILIM (A)
RILIM (kΩ)
ILIM (A)
RILIM (kΩ)
0.35
367.65
1.5
84.71
0.4
321.52
1.6
79.33
0.5
256.93
1.7
74.58
0.6
213.88
1.8
70.36
0.7
183.12
1.9
66.58
0.8
160.06
2.0
63.18
0.9
142.12
2.1
60.11
1.0
127.77
2.2
57.31
1.1
116.02
2.25
56.01
1.2
106.24
—
—
1.3
97.96
—
—
1.4
90.86
—
—
10 11
t ICHGR (ms)
TICHGR
(m s)
Figure 22. Charging Current External Capacitor (CICHG)
Versus Charging Current Rise Time (t ICHGR)
OVERCURRENT LIMIT
Choosing the External Resistor RILIM Value
The user can change the current limit by adding a resistor
(RILIM) between the ILIM and VIN pins, as shown in
Figure 19, page 18. This way the 34652 device is adaptable
400
350
300
RILIM (kohm))
When in normal operation mode, the 34652 monitors the
load and compares (with a hysteresis) the current going
through a Sensor MOSFET with a reference current value
generated in reference to the current limit value ILIM. If the
current going through the Sensor MOSFET becomes larger
than the reference current for more than 100 µs, the
overcurrent signal is asserted, the gate of the Power
MOSFET is discharged fast (in less than 10 µs) to try to
regulate the current, and the 34652 is in overcurrent mode for
3.0 ms. If after a 3.0 ms filter time the device is still in
overcurrent mode, the device turns off the Power MOSFET
and deactivates the power good output signals. The 34652
then initiates another start-up timer and goes back through
the enhancement process. If during the 3.0 ms timer the fault
was cleared where the load current was less than ILIM minus
the hysteresis value, which is 12% of ILIM value, then the
34652 goes back to the normal operation mode and the
power good output signals stay activated. This way the
device overcomes temporary overcurrent situations and at
the same time protects the load from more severe
overcurrent situations.
When the device passes the UVLO threshold, it checks if
there is any external resistor connected to the ILIM pin. If
there is, it determines the value of the overcurrent limit. If
there is not, it uses the default overcurrent limit value of 1.0 A.
It then uses the Sensor MOSFET to monitor the load for any
overcurrent conditions during operation as explained in the
previous paragraph.
250
200
150
100
50
0
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4
ILIM (A)
Figure 23. External Resistor (RILIM) Value Versus
Current Limit Value (ILIM)
34652
22
Analog Integrated Circuit Device Data
Freescale Semiconductor
TYPICAL APPLICATIONS
SHORT CIRCUIT DETECTION
3500
If the current going through the load becomes > 5.0 A, the
Power MOSFET is discharged very fast (in less than 10 µs)
to try to regulate the current, and the 34652 is in the
overcurrent mode for 3.0 ms. Then it follows the pattern
outlined in the Overcurrent Limit paragraph above.
Figure 24 shows a projected energy capability of the
device’s internal Power MOSFET under a drain to source
voltage of 82 V and an ambient temperature of 90°C. It is
compared to the energy levels required for the capacitive
loads of 100 µF, 200 µF, and 400 µF at 80 V for the
discharge periods of 16 ms, 32 ms, and 64 ms, respectively.
It is clear that the Power MOSFET well exceeds the required
energy capability for all three cases with a sufficient margin.
For example, the 400 µF capacitor load with a 64 ms
discharge time requires an energy capability of about
1540 mJ, which is well below the Power MOSFET capability
of about 3500 mJ. As a result of this analysis, the 33652 is
expected to more than meet all energy capability
requirements for the possible capacitive loads.
200 µF
2500
Energy (mJ)
POWER MOSFET ENERGY CAPABILITY
Estimated for Area =1.7 mm2
400 µF
3000
100 µF
2000
1500
1000
500
0
0
20
40
60
Time (ms)
Figure 24. Projected Energy Capability of the Power
MOSFET Compared to the Required Energy Levels of
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
23
PACKAGING
PACKAGE DIMENSIONS
PACKAGING
PACKAGE DIMENSIONS
Important For the most current revision of the package, visit www.freescale.com and perform a keyword search on the “98A”
drawing number below:
EF SUFFIX (Pb-Free)
16-PIN SOIC NARROW BODY
PLASTIC PACKAGE
98ASB42566B
ISSUE M
34652
24
Analog Integrated Circuit Device Data
Freescale Semiconductor
REVISION HISTORY
REVISION HISTORY
REVISION
DATE
DESCRIPTION OF CHANGES
6.0
2/2006
•
Changed Document Order No.
7.0
6/2006
•
•
•
Changed Max on DISABLE Input Current
Changed Overcurrent Limit in Steady State and in the text on page 11 and page 22
Updated PACKAGE DIMENSIONS on page 24
8.0
2/2007
•
•
•
Updated to the current Freescale format and style
Added Part Number MCZ34652 in the Ordering Information
Removed Peak Package Reflow Temperature During Reflow (solder reflow) parameter from
Maximum Ratings on page 5.
Added Note Freescale’s Package Reflow capability meets Pb-free requirements for JEDEC
standard J-STD-020C. For Peak Package Reflow Temperature and Moisture Sensitivity Levels
(MSL), Go to www.freescale.com, search by part number [e.g. remove prefixes/suffixes and enter
the core ID to view all orderable parts. (i.e. MC33xxxD enter 33xxx), and review parametrics. on
page 5
•
34652
Analog Integrated Circuit Device Data
Freescale Semiconductor
25
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MC34652
Rev. 8.0
2/2007
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