CALMIRCO CM9112-00QE

PRELIMINARY
CM9112
Dual Inputs Dual Outputs High Accurate Fast Charger
Features
Product Description
•
The CM9112 is an integrated linear-mode charger for a
single-cell, Lithium-ion battery. It provides both charg­
ing current for the battery and power for the host sys­
tem. It can deliver charging current up to 1A and
system current up to 450mA at the same time. It takes
power either from AC Adapter or USB Adapter. When
both are present it automatically chooses AC Adapter
as input.
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Monolithic linear charger requires no inductors,
external sense resistors or blocking diodes
4.75V to 6.50V operating input voltage range
It can support up to 30V on Adaptor input and 7V
on USB input
Up to 1.5A total system and charging current
Provides power to the host system and charges
the battery at the same time
Supports AC wall adapter and USB input
4.2V/450mA, available for host system under
Adapter input
It provides 0.5% accuracy of CV mode for 4.2V
An optional 0.1µF cap on CT pin programs 30 min./
60 min. timeout for Precharge/Termination.
Two Thermal limits controls chip temperature and
prevents overheating
Remote sensing pin for Battery voltage
Pin to pin shortage protection
Maximum of 1µA battery drain current
Optional Battery thermistor (NTC) interface
TQFN-16, RoHS compliant lead-free package
It requires no external blocking diodes or current sense
resistors and uses 2 external resistors to program dif­
ferent charging current under AC Adapter or USB
inputs.
The CM9112 provides Precharge Mode, Constant Cur­
rent Mode (Fast-charge), Constant Voltage Mode and
Termination by low current detection. Programmable
timeout for Precharge and Termination and Thermistor
interface to check Battery Temperature are optional
available to the users.
The CM9112 is protected against the use of a wrong
high voltage Adapter up to 30V. An antiringing protec­
tion on Adaptor input allows the use of a cheaper adap­
tor without need of a shock inductor.
Applications
•
•
•
Pin to pin shortage protection makes it friendly to the
users against accidental handling during mounting or
checking. The CM9112 is packaged into a miniature
16-pin TQFN package and operates between –40°C
and 85°C ambient.
Cellular phones and smart phones
Pocket computers and PDAs
Digital Still Camera
Typical Application
Q1
AD
(AC
Adapter )
VIN
1k
STAT1 STAT2
VSYS
GAD
VREF
VAD
VOUT
33
USB
USB
Q2
4.2V/450mA
BSEN
THERM
ISET1
0.1u
4.7u CM9112
GND
ENA
4k
CT
ISET2
SYSTEM
1k
Li-ion Battery
10k
NTC
5k
2.5k
0.1u
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
1
PRELIMINARY
CM9112
Package Pinout
PACKAGE / PINOUT DIAGRAM
TOP VIEW
BOTTOM VIEW
11
10 THERM
10
9 STAT1
9
16
VSYS
13
15
GAD
14
14
GND
PAD
2
3
4
5
11 VOUT
1
6
12
7
VAD
15
13
12 BSEN
8
4
(Pins Up View)
STAT2 8
VREF
CT 7
3
ENA 6
2
ISET2 5
GND
ISET1
00QE
1
CM9112
USB
VIN
Pin 1
Marking
16
(Pins Down View)
CM9112-00QE
16-Lead TQFN Package (4mm x 4mm)
Note: This drawing is not to scale.
PIN DESCRIPTIONS
LEAD(s)
NAME
1
USB
USB compliant power input pin.
2
GND
Ground pin.
ISET1
Pin to set the maximum USB input current; Also, reflects actual charging current. A
resistor between this pin and ground sets the charge current,
3
4
ICH,
× 2.5V
RISET1 = 1000 -----------------------------I CC VREF
4.2V, 2mA reference output pin.
ISET2
Pin to set the maximum charging current in the Fast charge (CC) mode. Also,
reflects actual charging current. A resistor between this pin and ground sets the
5
6
DESCRIPTION
charge current, ICH,
ENA
CT
7
1000 × 2.5V
RISET2 = -----------------------------ICC Enable pin. Logic high (default value) enables charging. Logic low disables charg­
ing. ENA does not effect the VSYS output.
Pin for capacitor, CT, for programming the Precharge and Termination timeout
period.
Timeout1[min]=300 x CT[μF]
Timeout2[min]=600 x CT[μF]
8
STAT2
Charging status indicator 2 pin (open-drain output).
9
STAT1
Charging status indicator 1 pin (open-drain output).
10
THERM
Thermistor input pin from battery monitoring circuit.
© 2006 California Micro Devices Corp. All rights reserved.
2
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
07/06/06
PRELIMINARY
CM9112
Ordering Information
PIN DESCRIPTIONS
11
VOUT
Charger output pin (Battery/RF High Power).
12
BSEN
Battery voltage remote sense pin.
13
VSYS
Power output pin to the host system 4.2V/450mA.
14
GAD
Gate drive to external P-MOSFET for adapter input pin.
15
VAD
Adapter input voltage pin.
16
VIN
Positive input supply voltage pin, which powers the charger.
PART NUMBERING INFORMATION
Lead Free Finish
Pins
Package
Ordering Part Number1
Part Marking
16
TQFN
CM9112-00QE
CM9112 00QE
Note 1: Parts are shipped in Tape & Reel form unless otherwise specified.
Specifications
ABSOLUTE MAXIMUM RATINGS
PARAMETER
RATING
UNITS
±1
kV
[GND - 0.3] to +6.5
V
[GND - 0.3] to +30
[GND - 0.3] to +7.0
[GND - 0.3] to +6.5
[GND - 0.3] to +6.5
[GND - 0.3] to +6.5
V
V
V
V
V
Storage Temperature Range
-65 to +150
°C
Operating Temperature Range (Ambient)
-40 to +85
°C
300
°C
ESD Protection (HBM)
VIN to GND
Pin Voltages
VAD, GND to GND
VOUT, VSYS, USB to GND
ENA, ISET1, ISET2 to GND
STAT1, STAT2 to GND
BSEN, VREF, CT, THERM to GND
Lead Temperature (Soldering, 10sec)
ELECTRICAL OPERATING CHARACTERISTICS (SEE NOTE 1)
SYMBOL
VAD
PARAMETER
VAD Operation range
VUSB
USB Operation range
IQ
Quiescent Current
CONDITIONS
MIN
4.75
TYP
5.0
4.50
Charging modes, exclud­
ing current to and STAT1,
STAT2 and THERM pins.
MAX
6.50
UNITS
V
5.25
V
2
mA
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
3
PRELIMINARY
CM9112
Specifications (cont’d)
ELECTRICAL OPERATING CHARACTERISTICS (SEE NOTE 1)
SYMBOL
ISHDN
IREV
PARAMETER
Shutdown Supply Current
Battery Reverse Current
CONDITIONS
ENA = "LOW", excluding
current to STAT1, STAT2
and THERM pins.
Both AC Adapter and
USB removed
MIN
VAD/USB Supply Voltage
UVLOVAD
UVLO threshold for VAD
OVPVAD
OVP threshold for VAD
UVLOHYS_VAD UVLO,OVP Hysterezis for
VAD
Total input current under
IIN_AD
Adaptor input
IIN_USB
4.75
6.2
TYP
50
MAX
100
UNITS
µA
0.5
1
µA
4.8
4.85
V
6.4
6.5
300
VIN=5.0V; Adaptor in
V
mV
IIN_AD =
ISYS + IVOUT
Total input current with USB VIN=5.0V; USB in, Adap­
plugged-in and Adapter out tor out
1700
mA
IIN_USB
=
mA
2500
---------------------------------R
SET1(kΩ) USB switch Rds(on)
Charger Function
IPR
Precharge Mode Current
IIN_USB = 500mA
VOUT < 3.2V; Adaptor in
0.85 x IPR
150
200
mΩ
IVOUT =
1.14 x IPR
mA
1.14 x IPR
mA
250
IPR = --------------------------R SET2 ( k Ω) VOUT < 3.2V; USB in,
Adaptor out
VCC
CC Mode Voltage Threshold
ICC
CC Mode Charging Current VOUT > 3.5V; Adaptor in
0.85 x IPR
IVOUT =
IPR
3.20
3.30
3.40
V
0.92 x ICC
IVOUT =
1.08 x
ICC
mA
1.08 x
ICC
mA
ICC
VOUT > 3.5V; USB in,
Adaptor out
VCV
ITERM
VRCH
0.92 x ICC
2500
= --------------------------R SET2 ( k Ω) IVOUT =
2500
ICC = --------------------------R SET1 ( k Ω) CV Mode Voltage Threshold
Charging Termination Cur­
rent
250
= --------------------------R SET1 ( k Ω) 4.190
4.200
4.210
V
VOUT > 4.190V; Adapter
in
0.8 x
ITERM
IVOUT =
1.2 x
ITERM
mA
VOUT > 4.190V; USB in,
Adapter out
0.8 x
ITERM
1.2 x
ITERM
mA
4.110
V
Recharge Mode Threshold
25
ITERM = --------------------------R SET2 ( k Ω) IVOUT =
25
I TERM = --------------------------RSET1(kΩ) 4.090
4.100
© 2006 California Micro Devices Corp. All rights reserved.
4
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
07/06/06
PRELIMINARY
CM9112
Specifications (cont’d)
ELECTRICAL OPERATING CHARACTERISTICS (SEE NOTE 1)
SYMBOL
CT
OTP
OCP
RDSON
TPR
TTER
VREF
VREF
PARAMETER
Constant-temperature
Mode, Limit
Over-temperature Protec­
tion, Limit
Over-Current Charging
(OCP), Limit
RDSON of Charger MOSFET
CONDITIONS
(Note 2)
MIN
95
TYP
105
MAX
125
UNITS
C
(Note 3)
130
140
150
C
1.5
1.7
1.8
A
ICC = 500mA
100
120
150
mΩ
Precharge Timeout
(Note 4)
Termination Timeout
(Note 4)
Adaptor in; BSEN < 3.2V,
CT=0.1µF, 1%
Adaptor in; BSEN >
4.19V, CT=0.1µF, 1%
27
30
33
Min.
54
60
66
Min.
Regulated Voltage VREF
IREF < 1mA
4.190
4.200
4.210
V
VSYS (Available only with Adapter plugged-in) (Note 5)
MOSFET RON
RDSON
VSYS
Output Voltage Load Regu­ IOUT = 10mA to 300mA
lation
IOUT = 10mA to 450mA
4.1
4.2
3.9
4.0
ISYS
Output Current available
10
3.9V<VSYS<4.3
Over-Current Shut-down
(Note 6)
Threshold
Control Function
BSEN Pin Leakage Current VIN = 0
IBSEN
1200
ILIMIT
VIH EN
VIL EN
ENA Input Low Level
Thermistor Function (Note 7, 8)
VBH
Battery HOT Voltage
Threshold (THERM Pin)
VBC
Battery COLD Voltage
Threshold (THERM Pin)
4.3
V
4.1
V
450
mA
1500
mA
0.2
STAT1, STAT2 (Open Drain) ISINK = 5mA
Output Low Voltage
ISINK = 20mA
ENA Input High Level
VSTAT1
VSTAT2
Ω
0.25
1.0
µA
0.1
0.5
V
V
0.4
V
1.5
V
VIN = 5.0V
(Note 9)
0.9 x VBH
VBH = 0.5 x VIN
1.1 x VBH
V
VIN = 5.0V
(Note 9)
0.9 x VBC
VBC = 7/8 x VIN
1.1 x VBC
V
80
100
120
mV
Hysterezis of VBH, VBC
Note 1: TA = 25°C unless otherwise specified.
Note 2: When chip temperature reaches 105°C, the IC’s internal thermal limit will maintain this temperature by decreasing the pro­
grammed charge current.
Note 3: When chip temperature reaches 140°C, the IC goes into a latched shutdown mode. It stops charging, stops supplying VSYS
with current from Adapter/USB, and switches VSYS (Baseband) to VOUT(Battery). To resume the charging function, a tog­
gle of VAD/USB is required.
Note 4: The timeout can be disabled by connecting the CT pin to VIN. When enabled, both Timeout1 and 2 are proportional to the
value of the capacitor connected on the pin CT. However, the ratio Timeout2/Timeout1 is constant and equal to two. The tim­
ing periods are digital, internally generated, based on a clock rate programmable by an external capacitor connected in the
CT pin. Timeout feature is available only with AC Adaptor plugged in. Under USB input, both timeout are disabled to allow
longer charging time due to low input current available.
Note 5: When both the Adapter and USB are removed, VSYS is switched over to battery, through an external MOSFET, Q2.
Note 6: When the VSYS maximum current limit is reached, LDO1 regulates this current by decreasing VSYS. However, VSYS can­
not go below VOUT (battery) by more than one diode’s forward voltage (Vfwd) due to the body diode of the external MOS­
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
5
PRELIMINARY
CM9112
Specifications (cont’d)
FET, Q2. When this condition occurs, the battery will provide extra current to keep VSYS constant at Vbatt-Vfwd. This lasts
until the power dissipated in LDO1 triggers the OTP. As a result, there will be no input current to supply either charging or
LDO1. Current will still be available from battery to supply VSYS, through the external Q2. To resume charging (after the
chip temperature drop bellow 120°C), the VAD/USB inputs must be toggled.
Note 7: This feature can be disabled by connecting the THERM pin to GND.
Note 8: This function requires that Battery Thermistor should be connected between the THERM pin and GND. Another resistor
connected between THERM pin and VIN is required, its value should equal the Thermistor Hot Value (at 50°C). In order to
catch both the 0°C and 50°C thresholds (typical range for Li-ion battery) use Thermistors following 7/1 ratio (Thermistor
COLD/Thermistor HOT=7).
Note 9: If the battery HOT/COLD detection identifies a condition outside the thresholds, the IC stops charging the battery and waits
for the temperature to return to the normal value. During this event, VSYS will continue to be supplied with the required cur­
rent.
Functional Block Diagram
GAD VIN USB Qb
VAD LDO1
450mA
0.03
OCP
Adapter
Current
Limit
OVP &
ADOK
VSYS S/D
LDO2
2mA
4.2V
VREF Qc / 1000
ISET2 OTP
GND VOUT Qc
Over-Temp
Limit
BSEN ENA Charger
Control
Timer
CT Current
Mirror
ISET1 THERM CM9112
STAT2 STAT1 © 2006 California Micro Devices Corp. All rights reserved.
6
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
07/06/06
PRELIMINARY
CM9112
Flow Chart
No
4.75V<VAD<6.5V
USB > 4.5V
ADOK=0
No
Sleep mode
Yes
Yes
Shut down LDO1 ,
VREF, Stop Charging
Connect VSYS with
Battery through
external Q2
VIN < BSEN
ADOK=1
ENA = High
Stop charging
Set STAT1=OFF,
STAT2=OFF
ENA has no effects
of VSYS output
No
Yes
STAT1
STAT2
Precharge in progress
ON
ON
Fast charge in progress
ON
OFF
Charge done
OFF
ON
Timer fault
OFF
OFF
Sleep mode
OFF
OFF
OCP
Iin > 1.5A
OTP
Set Precharge Mode
STAT1=STAT2=ON
Start Timeout 1
Tj > 150 oC
Precharge
Mode
Shut down LDO, VREF,
Stop charging and Latch ;
Set STAT1=STAT2=OFF
Connect VSYS with Battery
through external Q 2
Shutdown mode
Battery hot ,
cold
or removed
No
ADOK=1
CHARGE STATE
No
Stop Charging
Set
STAT1=STAT2=OFF
2.5V<THERM
<4.375V
Yes
Yes
2500
RISET2
Start Timeout 1; IVOUT
VSYS=4.2V/500 mA
IVOUT
2500
RISET1
Yes
Battery
Temperature
Checking
BSEN < 4.200V-100mV
No
No
BSEN > 3.3V
CC Mode
Charge time >
Timeout 1
Yes
ADOK=1
Yes
2500
R ISET2
Stop charging
and Latch. Set
STAT1=STAT2=OFF
IVOUT
No
2500
R ISET1
Stop charging
Stop Timeout 2;
Set STAT1=OFF
STAT2=ON
Timer
Fault
Yes
Yes
No
No
Charge Done or
Battery is not
present
Yes
Set CC mode
STAT1=ON,
STAT2=OFF
IVOUT
Yes
ADOK=1
Standby
Mode
IVOUT <=
Yes
Charge time > No
Timeout 2
Reset
Timeout 2
120
R ISET1
Yes
CV Mode No
No
BSEN >= 4.200V
YesCV Mode
Set
IVOUT<=
Start Timeout 2
ADOK=1
No
120
R ISET2
Yes
Note: If Therm is used, during any charging mode, removing a battery will cause the CV mode, then termination, the equivalent to charge done. Until the battery is returned, the charger will cycle between standby mode and re-charge cycle. © 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
7
PRELIMINARY
CM9112
Application Information
The CM9112 is an integrated charger with a charging
profile tailored for single-cell graphite electrode (anode)
Li-ion batteries. This linear charger can be powered
from either an AC voltage-source adapter or a USB
port. When both are applied it will automatically select
the AC Adaptor source.
The charger features the three modes required for a
safe and reliable Li-ion charging profile; Precharge,
Fast-charge, and Termination charge. Extensive safety
features include battery temperature monitoring, volt­
age and current monitoring and charging time limits.
Two charging status indicators provide charge state
information.
Two different external resistors Riset1,Riset2 allow two
different charging current to be programmed for either
USB adaptor or AC Adaptor. This method allows an
accurate control of USB input current.
Under AC Adaptor input both VSYS (host system) and
VOUT (battery) are simultaneously supplied with the
current required by each oh them, independently.
When the absolute over current limit protection is
reached (1.5A), CM9112 goes into shutdown, latched
mode.
Under USB supply, with AC Adaptor out, CM9112 pro­
vide power only to VOUT. The total current available for
VOUT is externally programmed by Riset1.
USB/AC adapter dual input
The CM9112 can support inputs from either a USB bus
or a 5V AC wall adapter.
The USB standard specifies a 5.0V +/-5% bus voltage,
capable of 500mA (High Power peripheral configura­
tion) of current. Since desktop and mobile PCs are
equipped with USB or USB2 connectors for interfacing
with peripherals and digital consumer electronics, it is
advantageous to tap the USB’s power to charge porta­
ble devices such as cell phones.
When using USB input power, the CM9112 will auto­
matically select external resistor Riset1 to fix the total
input current. This goes only into VOUT pin and is
intended to charge the battery. However, the system is
connected to the battery through a Schottky diode.
This makes possible some current flowing into VOUT
pin to go not only into Battery but into System too. A
longer charging time will be the result of this. That’s
why, under USB input, timeout for charger are disabled.
When using AC Adaptor power, CM9112 will automati­
cally select the resistor Riset2 for charging current. In
addition of this it will provide a free current to VSYS
directly from Adaptor input through a power LDO. This
will be limited to 450mA either by power dissipated on
the chip, or absolute current limit.
When using a constant-voltage, 5VDC nominal, AC
adapter, the semi-regulated voltage to the charger,
after accounting for the conduction losses through the
power cord and connector contacts, is a voltage in the
range of 5.0V to 6.0V. When a valid AC adapter voltage
between 4.75V and 6.5V is detected on the VAD pin,
an external MOSFET, Q1 is turn ON and VAD and VIN
are connected together. An internal power MOSFET
used for USB supply, is turned OFF, so there is no
residual voltage on USB pin due to VAD supply. The
same, when USB is used as input. No residual voltage
in VAD pin.
Charging Li-ion Batteries
Once the CM9112 detects the presence of either a
valid AC adapter or USB input voltage, and checks that
the battery voltage at BSEN is less then VIN and that
the battery temperature is within the correct range, it is
ready to charge the Li-ion battery. The controller’s
internal counter is reset.
If the battery voltage is deeply discharged (less than
3.2V), the CM9112 will start in the Precharge mode,
charging at 10% of the programmed Fast-charge cur­
rent level. See Figure 1. While the battery is charging,
the status pins will be set to STAT1=0 and STAT2=0.
The Precharge current will gradually bring the battery
voltage to above 3.2V. If the battery does not reach the
3.2V level, indicative of a defective Li-ion cell, the
CM9112 will turn off the charging process after a Precharge timeout period (Timeout1, 30 minutes per
0.1µF of CT capacitance). In this case, the status pins
will be set to STAT1=VIN and STAT2=VIN.
© 2006 California Micro Devices Corp. All rights reserved.
8
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
07/06/06
PRELIMINARY
CM9112
Application Information (cont’d)
Current
PreCondition Constant Current (4.20V – VOC) and the internal impedance, Rinternal, of
the Li-ion battery-pack. When it reaches termination
current limit, stop charging is triggered and the Battery
is fully charged.
Termination CV Charging Voltage Charging Current 4.0V Following the Termination mode, the charger will enter
the Standby mode. The status pins will be set to
STAT1=VIN and STAT2=0.
3.0V 2.0V Figure 1. Typical Li-ion Battery Charging Process
If the wall adapter or USB input is left plugged-in while
in the Standby mode, the charger will continue to mon­
itor the battery voltage. It automatically re-charges the
battery when the battery voltage drops below the re­
charge threshold. When the adapter is removed, the
CM9112 will drain less than 1µA from the battery.
Once the battery voltage exceeds the 3.3V threshold,
the CM9112 enters the Fast-charge, constant-current
(CC) mode. The status pins will be set to STAT1=0 and
STAT2=VIN. During the CC mode, the charging current
is limited by the maximum charging current, pro­
grammed with a single resistor between ISET1 for USB
and ISET2 for adaptor:
VIN The actual Fast-charge current might be further limited
by the maximum chip temperature limit, determined by
the power dissipation on the CM9112 chip, the ambient
temperature (TA), and the junction-to-ambient thermal
resistance, Rth(JA). The current requested by System,
ISYS, might have a significant contribution to the power
dissipated on the chip and reduction of the charging
current. So, it is recommended to reduce as much as
possible the ISYS current during charging. However,
there is not timeout for fast charge period. So, there is
no risk to stop the charging, just delay of it.
When the battery voltage reaches 4.200V it goes into
CV mode and CM9112 turn from a constant current
source to a constant voltage source. As a result, the
charging current start dropping. The actual charging
current is now determined by the differential voltage
I CH
Conventional
Floating
Charger
2.5V × 1000
IFASTCHG ( max ) = --------------------------------
RISET1, 2
Most battery manufactures recommend an optimal
charging current for their battery. This is typically a time
ratio related to the battery capacity, with a value of .7C
to 1C, once the battery is above the Precharge voltage
level. For example, a 750mAh capacity battery with
recommended charge of .7C could have ICC set for
about 525mA, with RISET2 equal to 4.75kΩ, 1%.
I SYS VOUT System
VBAT Figure 2. Conventional Charger
Limitations of Conventional Chargers
In a conventional floating charging architecture, the
system load is always tied directly to the battery, as
shown in Figure 2. If the adapter is charging a deeply
discharged battery in the Precharge mode, the system
input voltage will be held below 3.2V, the same voltage
as the battery voltage. This charger output voltage may
be too low to allow a user to use the system, even for
non-transmitting (low power) tasks, such as composing
emails. Further, in the Precharge mode, the battery
charge current is typically limited to 100mA or less. If
the system is trying to power up, it may draw more cur­
rent than the Precharge current limit allows. In this con­
dition, the system will continue to drain power from the
battery, potentially causing the battery charger to
remain stuck in a Precharge mode indefinitely. After the
Precharge timeout expires, the charger, thinking it has
a defective battery, will shut down, and the battery is
never charged beyond the Precharge mode.
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
9
PRELIMINARY
CM9112
Application Information (cont’d)
When using conventional floating charger with the sys­
tem load connected directly to the battery, and in the
CC mode, where a higher current limit is available, for
example, the system can draw a continuous load cur­
rent of 300mA. However, since the system is always
tied to the battery, the charger IC has no way to differ­
entiate the system power demand from the battery
charging demand. The charger will limit the total output
current to 300mA for the system and 1A for charging
the battery. If the battery voltage is low, 3.2V for exam­
ple, the charger IC power dissipation will be at its worst
case, or 3.6W. The charger’s junction temperature
rises quickly, triggering the over-temperature (OT) cur­
rent foldback. If the system continues to draw a large
current, the battery will then be supplying part of that
load current; putting the battery is in a discharge mode,
rather than in a charge mode. The battery voltage will
continue to drop, potentially falling back into a Precharge mode condition, and upsetting the charging
sequence or forcing the charger to shut down.
Even the charger power dissipation due to the system
load alone:
VIN VSYS
LDO1
4.2V
I SYS VREF
System
CM9112
VOUT
Charger
ICH
BSEN
VBAT Figure 3. Dual Outputs Charger
Since the CM9112 provides an independent power
path to the system, as soon as an adapter is pluggedin, the user can use the system power, even if the bat­
tery is dead or in the Precharge mode.
Charging Current Foldback in the Overtemperature Condition
PD1 = 1.0A × (5V – 3.2V )= 1.8W may already exceed the chip’s thermal limit and cause
OTP to trigger.
The CM9112 Dual Outputs Charge Advantage
To overcome these issues, the CM9112’s Fast-charge
architecture separates the system power output
(LDO1) from the battery charging power output. See
Figure 3. With a separate output, the power dissipation
contributed by LDO1 in a condition similar to the one
above is now only:
PD1 = 1.0A × (5V – 4.2V )= 0.8W In other words, the LDO1 can support the system load,
free from the hindrance of the charger, regardless of
the battery voltage level. The user can continue use
the host system, even when the battery charge voltage
is very low, when there is a defective battery, or there is
no battery present.
A limitation of linear chargers is that they are vulnera­
ble to over-temperature conditions. The CM9112 will
throttle down the charging current when the chip junc­
tion temperature reaches 105°C (with 10°C of hys­
terezis). This protects the charger IC and its nearby
external components from excessive temperature.
The Charger IC junction temperature is determined by
several factors in the following equation:
(1)
TJ = TA + PD + Rth(JA) The Rth(JA) is usually determined by the IC package
and the thermal resistance between the package and
the PC board. In particular, a SMD IC package relies
on the underlying PC board copper to move the heat
away from the junction. The key to reducing the ther­
mal resistance between the IC package and the under­
lying PC board is using a large copper (Cu) area for
solder attach and a large ground plane underneath the
charger IC to conduct the heat away.
The power dissipation (PD in equation 1) of a linear
charger is the product of input-output voltage differen­
tial and output current.
© 2006 California Micro Devices Corp. All rights reserved.
10 490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
07/06/06
PRELIMINARY
CM9112
Application Information (cont’d)
The Need for OVP
PD = (V IN – V OUT ) × IOUT In most cases, VIN is fixed at about 5.0V (either the AC
adapter or the USB power input). The CM9112 has two
outputs; one for the charger and one for the system
from LDO1. The total power dissipation is:
PD = (5V – 4.2V ) × ISYS + (5V – V BAT ) × I FASTCHG Highest power dissipation occurs when the battery at
its lowest level (3.2V), when it just starts in the Fastcharge (CC) mode. Assuming VIN = 5.0V, VBAT = 3.2V,
ICC = 1A, the PD = (5V-3.2V) x 1A = 1.8W. Assuming
Rth(JA) = 50°C/W, then ΔT = 1.8W x 50°C/W = 90°C. If
the ambient temperature (TA) is 35°C, then the junction
temperature (TJ) could reach 125°C without over-tem­
perature current foldback.
With over-temperature (OT) current foldback, the
CM9112 will throttle down the charging current, allow­
ing the junction temperature will reach steady-state
equilibrium of 105°C, which translates into 1.4W of
power dissipation, or 0.78A of charge current. As the
battery voltage rises during charging, the allowable PD
dissipation is increased. When the battery voltage
reaches 3.6V, a full 1.0A of charging current is allowed.
Dual-Level OTP and OCP
In addition to chip temperature regulation at 105°C, the
CM9112 provides absolute over-temperature shutdown
protection. In the case of a malfunctioning charger con­
trol, high ambient temperature or an unexpectedly high
IC thermal resistance, Rth(JA) (for example; due to
faulty soldering of the charger IC chip), the power dissi­
pation from LDO1 alone could over-heat the device.
The CM9112 provides an absolute OTP shutdown at
junction temperature of 150°C.
Similarly, each output, LDO1 and VOUT (ISET2), has
its own current limit. ISET1 provides the total adapter
current limit for adaptive charging current control. How­
ever, in case of an inoperative ISET2 setting (for exam­
ple; RISET2 becomes shorted to ground), ISET1 will
function as backup over-current protection. Combining
the dual-level OTP and the dual-level OCP, the
CM9112 in effect provides four layers of protection
against charger or VSYS over-load faults.
There are two primary reasons for adding an input
OVP feature to the CM9112 charger. One is to protect
the charger and the host system when an adapter with
the wrong output voltage is plugged-in. The other is to
protect the charger IC and the system against input
surge voltage resulting from the ringing due to the input
capacitor and an inductive adapter power cord.
Almost all computer peripherals and consumer elec­
tronics use AC adapters. It is common to use an LCD
monitor, a printer, a laptop computer, an ADSL or cable
modem, a cell phone, an MP3 player, with all their indi­
vidual AC adapters clustered around a power strip. The
output voltages of these adapters vary, yet most of
these use a similar cylindrical style connector at the
device interface. Thus, the chance that a user might
plug-in a wrong adapter should not be taken lightly.
The CM9112 provides over-voltage protection (OVP)
against the plug-in of a wrong adapter, up to an output
voltage of 30V. The CM9112 drives a 30V P-type
power MOSFET as a disconnect switch. The propri­
etary OVP design of the CM9112 protects itself and the
host system against the intermittent connection of a
wrong adapter.
Another source of over-voltage comes from voltage
ringing that occurs when an adapter is first plugged-in,
as shown in Figure 4. A long power cord from the
adapter output can have an inductance of several µH,
and the input capacitor of a cell phone is typically a
10µF to 100µF ceramic, with very low ESR. Unfortu­
nately, the low resistance in the power cord and the low
ESR of the input capacitor provide little dampening to
this LC circuit, resulting in strong ringing, with input
voltage overshoot, when the adapter is first plugged-in.
The ringing could apply a peak voltage twice that of the
nominal adapter output voltage at the input capacitor
point.
The CM9112 can withstand several forms of OVP con­
ditions; DC, DC with ringing, or intermittent contact of
any frequency.
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
11
PRELIMINARY
CM9112
Application Information (cont’d)
reaches the normal operating temperature range.
Charging below freezing must be avoided because
plating of lithium metal could occur. Battery capacity
will be reduced if charged between 0°C and +10°C due
to the inefficient charging process at low temperatures.
Q1 Gate
Drive
The CM9112 has incorporated a thermistor interface,
responsible for the temperature control of the batterypack through a negative temperature coefficient (NTC)
thermistor attached near the battery-pack. The inter­
face surveys the voltage on the THERM pin, which an
input to a window comparator with thresholds associ­
ated with two battery-pack fault conditions:
Vdc
Figure 4. Q1 Response to Undamped Ringing at the Input
Vtherm<1/2 x VIN for Battery Hot
Vtherm>7/8 x VIN for Battery Cold
To avoid oscillation near the Vtherm thresholds, both
windows have an associated hysteresis of 200mV.
Charging status
CM9112 provides two charging status indicator pins:
STAT1 and STAT2. These are open-drain outputs,
which can drive LEDs directly, with up to 20mA of cur­
rent sinking capability. Alternatively, the system super­
visory microprocessor can monitor the battery charging
status by interfacing with these two pins, using a
100kΩ pull-up resistor for each pin. See Table 1.
CHARGE STATUS
Precharge in progress
Fast-charge in progress
Charge completed
Charge suspended
(including thermistor fault,
Precharge or Termination
timeout, OTP, OCP and
ENA pulled low)
STAT1
Low
Low
High
Rc(28K)
30K 20K Thermistor
Resistance
10K +
7/8*Vin
0 Vtherm
COLD
STAT2
Low
High
Low
HOT
High
Table 1: Charge Status for STAT1, STAT2
Thermistor Interface
Li-ion batteries are prone to overheating when exposed
to excess current or voltage. High heat, combined with
the volatile chemical properties of lithium, can cause
fire in some cases. The CM9112 provides a thermal
interface for over-temperature protection, allowing safe
charging of Li-ion cells.
For safety, manufacturers suggest suspending any
charging above 45°C and below 10°C until the battery
1/2*Vin
OK
0oC
High
Rh(4K)
20oC
40oC
60oC
Figure 5. Vtherm Windows
If the voltage on the THERM pin either exceeds 7/8 x
VIN, or goes below 1/2 x VIN, the CM9112 stops charg­
ing and STAT1, STAT2 signal a fault condition (both go
high). LDO1 remains fully functional and continues to
provide the necessarily current to VSYS (the Base­
band load). The charging resumes only when the volt­
age on the THERM pin returns to within the window of
1/2 x VIN to 7/8 x VIN. Figure 5 illustrates these win­
dows.
The thermistor interface consists of a thermistor con­
nected between THERM pin and ground, and a resis­
tor, Rtherm, connected between the THERM pin and
© 2006 California Micro Devices Corp. All rights reserved.
12 490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
07/06/06
PRELIMINARY
CM9112
Application Information (cont’d)
VIN, as shown in Figure 6. To determine the proper
value for Rtherm, the thermistor used in the batterypack should follow the 7:1 ratio on the Resistance vs.
Temperature curve (for example, Vishay Dale’s R-T
Curve 2):
·
R cold (at φ 0°C) --------------------------------------- = 7
Rhot (at φ 50°C) A thermistor with a room temperature value of about
10kΩ, or higher, will keep the interface current drain
from VIN low. Choose the Rtherm value equal to Rhot,
with a 0.5% tolerance. A metal film resistor is best for
temperature stability.
For example, a typically used thermistor for this appli­
cation is Vishay Dale’s NTHS0603N02N1002J. This
thermistor has a Rhot (50°C) = 4kΩ and Rcold (0°C) =
28kΩ. The thermistor interface will work properly if
Rtherm is 4.02kΩ, 0.5%. At 25°C the thermistor value
is 10kΩ. Therefore, a value of voltage at the THERM
pin will be:
10kΩ
Vtherm=
×5V = 3.57V 25o C
14kΩ Vtherm=
4kΩ ×5V = 2.5V 50o C
8kΩ Vtherm=
28kΩ
×5V = 4.375V 0o C
32kΩ VIN
NTC
VOUT
Charger
Battery
Pack
BSEN
If there is no need for the thermistor interface, the
THERM pin could be used as a second ENABLE pin
for charging control. If the system has an additional
control condition for stop charge, then the THERM pin
could be used as a second control input. Connecting
the THERM pin to VIN will stop charging, while pulling
to GND will resume charging.
Timeout Intervals
CM9112 provides two Timeout intervals: Timeout1,
which limits Precharge time and Timeout2, which limits
the Termination time. These intervals are digitally pro­
duced based on an internal clock signal. Timeout1
counts 131072 (217) clock cycles and Timeout2 counts
262144 (218) clock cycles. The ratio of Timeout2/
Timeout1 = 2 is fixed by the design, but the absolute
Timeout values are programmable by an external
capacitor, Ct, connected between the CT pin and GND.
This capacitor is responsible for the clock cycle rate.
Timeout1 time can be calculated as:
THERM
CM9112
When using the CM9112 with a dummy battery, without
a thermistor attached, this function can be disabled by
connecting the THERM pin to GND. In this case, the
THERM interface will never provide a fault condition to
stop charge.
A programmable timer is used to terminate the Precharge and Termination charge modes. There are
three modes in a normal charging procedure; Precharge, Fast-charge (or CC Mode), and Termination (or
CV Mode). Because the first and the third modes take
place at low currents, any failure of the battery (for
example, excessive leakage current) could cause
these modes to continue indefinitely if there was not a
Timeout limit.
Rtherm (4k)
Thermistor
Interface
Because the thermistor is typically located on the bat­
tery-pack, removal of the battery-pack will remove the
thermistor, and cause value of voltage at the THERM
pin to go above the window and thus stop charging.
This allows the THERM interface to function also as a
battery present detector.
Vishay
NTHS0603N02N1002 J
Timeout 1 = 217 x
Figure 6. NTC Thermistor Interface
13.6ms ⋅ Ct
(in minutes)
0.1uF ⋅ 60
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
13
PRELIMINARY
CM9112
Application Information (cont’d)
A value of 0.1µF provides a 13.6ms clock cycle period,
producing 30 minutes for Timeout1 (Precharge) and 60
minutes for Timeout2 (Termination),.
tion. The charging algorithm then will be controlled only
by voltage on the BSENS pin (Battery Sense Voltage).
When VIN is applied to a fully discharged battery
(VBAT<3.0V), the internal counter starts counting clock
cycles for Timeout1. A constant Precharge current
(10% of the programmed Fast-charging current) then
charges the battery. If Timeout1 elapses before the
battery reaches the 3.3V threshold of the Fast-charge
(CC) mode, charging stops and a Charge Suspended
fault
is
signaled
by
the
status
pins
(STAT1=STAT2=VIN). This is a latched status and
charging can only resume by toggling VIN.
Mode Summary
If the battery voltage attains 3.3V before Timeout1
elapses, the internal counter is reset without any action
from the charging algorithm and the battery goes into
the Fast-charge mode.
During the Fast-charge mode, there is no Timeout
counting, and, in theory, this mode can last indefinitely.
During Fast-charge, the battery could be providing cur­
rent to a load. With only part of the available charging
current going into the battery, the charging time will
increase and becomes unpredictable. Thus, a Timeout
interval during this mode is not used, allowing greater
application flexibility.
Once the battery reaches the 4.20V threshold, the Ter­
mination (CV) mode begins and the charging current
starts to decrease. At the same time, the internal clock
starts counting again. If Timeout2 elapsed before the
Termination current threshold is reached, charging
stops in a latched status (STAT1=STAT2=VIN). It can
resume only by toggling VIN. If the Termination thresh­
old is reached before Timeout2 has elapsed, the
counter resets and the charger enters into the Standby
mode.
Precharge mode is the typical charge starting mode
for pre-conditioning a deeply discharged battery
(<3.3V). A constant current of 10% of the programmed
Fast-charge current is applied to raise the voltage
safely above 3.3V. The maximum charge time is limited
to the programmed Timeout1 period.
Fast-charge mode is the constant current charging
mode that applies most of the battery charge. A pro­
grammed constant current is applied to bring the bat­
tery voltage to 4.2V.
Termination mode is the final charging mode, where a
constant voltage of 4.2V is applied to the battery until
the charge current drops below 5% or the programmed
Fast-charge current. The charging time is limited by the
programmed Timeout2.
Standby mode is entered after a successful Termina­
tion mode and charging is done. Charging stops but
VSYS continue to be supplied by AC Adaptor input. In
this mode, the battery is monitored, and when its volt­
age drops below the re-charge threshold (4.100v), a
new charge cycle begins.
Shutdown– not latched mode is triggered by a charg­
ing fault. These include THERM pin voltage outside the
window (battery is too hot, too cold, or removed), or
pulling ENA pin low. The charging resumes if the failure
condition is removed. VSYS is still alive and supply
SYSTEM with current.
Shutdown– latched mode
Disabling the Timeouts
If input current, sensed internally, exceeds 1.5A (OCP),
or the IC junction temperature exceeds 150°C (OTP).
The shutdown happens again but this time it is latched.
Only by toggling VAD/USB and removing the failure
condition the CM9112 could resume the function.
VSYS is no more supplied with current and an external
Q2 MOSFET connect VSYS with the Battery which
become the system power supplier.
To allow design flexibility for many different applica­
tions, the CM9112 allows disabling the Timeout inter­
vals as an option. If the application does not require
Timeout Intervals to control Precharge and Termina­
tion, connecting the CT pin to VIN will disable the func­
Timer-fault mode is entered when a Timeout ends
without the battery reaching the proper threshold.
Charging stops and remains stopped until VIN is tog­
gled. VSYS will continue to receive power through
LDO1.
If a stop charge to the battery is triggered by Timeout1/
Timeout2, it should be noted that VSYS would continue
to provide power to the Baseband load.
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
14
PRELIMINARY
CM9112
Application Information (cont’d)
Sleep mode is entered when the Adapter or USB is
removed (or is the wrong voltage). Charging stops and
VSYS is connected to the battery through Q2. In this
mode, the CM9112 draws less than 1µA of current
from the battery.
Typical Smartphone Applications
A Smartphone is a cellular or mobile phone with
special computer-enabled features not previously
associated with telephones, such as advanced data
functions. Most mobile phone includes some amount of
memory uses such as storing a phone directory, and
most can send and receive text messages, but a
smartphone can perform many more functions,
including PDA, an internet browser, a TV receiver, a
multi-pixel camera, or an MP3 player. Compared to
standard cell phones, smartphones usually have
larger, more colorful displays, contain processors that
are more powerful, and typically run operating system
software. These features are all packed into a smaller
box. This sophistication requires more battery power
than a simple cell phone.
1. In normal battery operation, Q2 is turned on, the battery supplies power to both the RF and Baseband loads. 2. GSM transmitter requires up to 2.0A of
pulse current. In the charging phase, both
the battery and adapter supply current for
the RF load.
Adapter
Q1
10u
100
GAD
Baseband
Load
VIN
LDO1
VSYS
0.1u
LDO2
VREF
The GSM is a TDMA (Time Division Multiple Access)
system where up to eight users share a transmitting
frequency channel. During transmitting, a GSM phone
can draw up to 2.0A of pulse current from the battery
(588 µs pulse width, at a duty cycle of 1/8).
When charging the cell phone battery and using the
cell phone at the same time, the power amplifier still
needs to draw 2A pulse current, which cannot be met
with an adapter having less than 2A of rated output
current capacity. Most adapters are rated at only 1A. In
order to charge the battery and use the phone at the
same time, the high-power section (mainly the RF
power amplifier), has to be supported by the battery at
all times, even when the adapter is plugged-in. See the
typical configuration in Figure 7.
With a discharged battery, the charger begins in the
Precharge mode, which will only supply 100mA or less
of charging current. In the case of very low battery volt­
age (typically below 3.2V), the cell phone is prohibited
from transmitting and drawing large current from the
battery.
The CM9112, with its integrated 4.2V, 450mA LDO out­
put, can support the low-power section of a cell phone,
such as the system microprocessor, LCD display and
LED backlight for the user interface. In addition, the
CM9112 can supply power to the system for non-trans­
mitting application such as reading and composing
email messages, or synchronizing data transfers
between a cell phone and a PC.
The CDMA phone demands lower peak current during
transmitting, typically 600mA peak. All the system
power can be supplied by LDO1 when configured as
shown in Figure 8.
33u
VAD
Smartphones are available in the two leading cell
phone topologies, CDMA and GSM. They each have
unique power demands.
Q2
0.1u
VOUT
RF
Load
Charger
BSEN
CM9112
GSM Phone
Figure 7. GSM phone application
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
15
PRELIMINARY
CM9112
Application Information (cont’d)
1. In normal battery operation, Q2 is turned on, the battery supplies power to the system load. 2. CDMA transmitter requires less than 500mA current. In the charging phase, the adapter alone can supply enough power
for the CDMA system load.
Adapter Q1
10u 100
GAD
VIN
LDO1
VSYS
Adapter 5V
IIN < ISET 1
=
Q1
VIN
GAD
System
Load
33u
VAD
0.1u LDO2
USB VREF
0.1u
VSYS
LDO1
0.03
Q2
Qb
4.2V
VOUT
VREF
LDO2
2mA
Charger
CM9112
I SYS
BSEN
Q2
VOUT
CDMA Phone
CM9112
VBAT
I CH
Qc
Figure 8. CDMA phone application
GND
Component Selection
The constant voltage AC Adapter must be selected
carefully to minimize power losses and heat dissipation
in the charger. The input supply should be between 5.0
and 6.0V. The lowest allowable input voltage will mini­
mize heat dissipation and simplify the thermal design.
An Adapter rated at 5.0V, 5% at the required input cur­
rent will provide adequate voltage for the VAD ADOK
window.
The output of LDO1, VSYS, requires a 33µF or larger
capacitor for good stability and minimum voltage droop
during the battery switchover to VSYS at the end of
charge. A low-ESR type capacitor will improve system
response to load transients. The output of VREF
(LDO2), the Q2 gate drive, requires a .1µF ceramic
capacitor for stability.
The CM9112 drives two external P-channel MOSFETs
(PMOS) to control the charging and system currents.
Refer to Figure 9. The most important specifications for
the pass PMOS transistors are current rating, RDS and
package power dissipation.
Figure 9. Current paths
In normal operation, Q1 is a fully turned-on switch
when an AC adapter is used. The worse-case power
dissipation for the input PMOS, Q1, is:
2
PQ1 = ISET1 ⋅RDS
The MOSFET Q1 and PCB heatsink must be rated for
this power. Q1 functions as a clamp to limit input volt­
age transients, and should be selected to handle the
worst-case Drain-to-Source voltage, 30V is suggested.
The RDS of Q1 should be low enough so that the volt­
age drop across it will not cause VIN to drop below the
minimum of 4.5V when the adapter is at its lowest out­
put. For example, if the adapter is 4.75V minimum at a
load of 1.0A and ISET1 is programmed to 1.0A:
R DS ≤
(4.75 V 4 .5 V )
= 250 m ∧
1 .0 A
Q2 is used to supply power to the system from the bat­
tery when not charging (adapter removed, end-of­
charge, OCP, OTP, etc.). This current passed through
Q2. The worse case power dissipation for Q2 would
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
16
PRELIMINARY
CM9112
Application Information (cont’d)
occur when LDO1 is disabled and the battery must
supply full system load.
2
PQ2 = Isys ⋅RDS
The Q2 and PCB heatsink must be rated for this power.
Layout Considerations
Because the internal thermal foldback circuit will limit
the current when the IC reaches 105°C it is important
to keep a good thermal interface between the IC and
the PC board. It is critical that the exposed metal on
the backside of the CM9112 be soldered to the PCB
ground. The Cu pad should is large and thick enough
to provided good thermal spreading. Thermal vias to
other Cu layers provide improved thermal perfor­
mance.
VIN, VSYS and VOUT are high current paths and the
traces should be sized appropriately for the maximum
current to avoid voltage drops. BSEN is the battery
feedback voltage and should be connected with its
trace as close to the battery as possible.
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
17
PRELIMINARY
CM9112
Mechanical Details
TQFN-16 Mechanical Specifications
Mechanical Package Diagrams
The CM9112-00QE is supplied in a 16-lead, 4.0mm x
4.0mm TQFN package. Dimensions are presented
below.
D
For complete information on the TQFN16, see the Cal­
ifornia Micro Devices TQFN Package Information doc­
ument.
E
PACKAGE DIMENSIONS
Package
TQFN-16 (4x4)
Leads
16
Millimeters
Inches
Min
Nom
Max
Min
Nom
Max
A
0.07
0.75
0.80
0.28
0.030
0.031
A1
0.00
0.05
0.00
A3
0.20 REF
0.30
0.35
0.010
0.012
0.014
D
3.90
4.00
4.10
0.154
0.157
0.161
1.95 REF
0.077
2.00
2.10
2.20
0.079
0.083
0.087
E
3.90
4.00
4.10
0.154
0.157
0.161
1.95 REF
2.00
e
2.10
0.45
2.20
0.079
0.65
0.018
0.083
0.087
A
D1
0.026
0.022
0.026
3000 pieces
E1
# per
tape and
reel
0.55
A3 A1
SIDE VIEW
0.077
0.65 TYP.
L
0.10 C
0.08 C
D2
E2
TOP VIEW
.008
0.25
E1
0.15 C
0.002
b
D1
0.15 C
E2
Dim.
Pin 1 Marking
Controlling dimension: millimeters
D2
L
DAP SIZE
1.8 X 1.8
b
e
16X
0.10
M
CAB
BOTTOM VIEW
Package Dimensions for 16-Lead TQFN
© 2006 California Micro Devices Corp. All rights reserved.
07/06/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l Tel: 408.263.3214
l Fax: 408.263.7846
l www.cmd.com
18