CALMIRCO CM9330

PRELIMINARY
CM9330
Asymmetrical High Efficiency Three Channel Boost LED Driver
Features
Product Description
•
•
The CM9330 is a high frequency, three-channel inductor-based PWM boost regulator specifically designed
for constant current white LED drive applications. With
a maximum 140mA/19V output capability, the circuit
can drive up to 15 WLEDs (5 series x 3 parallel) allowing up to 35 mA per channel. With a typical input voltage range from 2.7V to 6.0V, it can be operated from a
single cell Li-Ion battery.
•
•
•
•
•
•
•
•
•
•
•
•
2.7V to 6V input voltage range
Up to 85% typical efficiency even for asymmetrical
channel loads in terms of LED number, LED current and LED dropout
Excellent 5 series x 3 parallel WLED drive capability
Up to 140 mA/19V output current/voltage
Independent current setting using an external low
power resistor for each channel (no ballast resistors)
No external frequency compensation needed
Low (<1%) LED output voltage and current ripple
Input undervoltage lockout and output over-voltage
protection
1 MHz fixed switching frequency (0.5 MHz option
available)
Uses small inductor and ceramic capacitors
Integrated low ON-Resistance (0.3 Ω) N-Channel
MOSFET switch
Disconnects LEDs during shutdown
Low profile TQFN-16 package
Optional RoHS compliant lead-free packaging
Applications
•
•
•
•
•
•
•
Drives white LEDs for backlighting color LCD
Cell phones
MP3 players
PDA, GPS
Digital Still Cameras
LED flashlights
Handheld devices
The proprietary FlexBoost™ architecture (patent pending) provides high efficiency (typical 85%) for a wide
input voltage range, even for asymmetrical channel
loads in terms of LED number, LED current and LED
type. A standard (non-interleave) version is also available using a MODE selection pin (not available for
mass production). The maximum LED current for each
channel is independently programmed with external
low-power resistors (no ballast resistors needed).
A 1 MHz constant frequency PWM saves board space,
allowing small, low-cost external components, and permitting designers to avoid sensitive IF bands in RF
applications. The output over-voltage protection circuit
prevents damage in the case of a high impedance output (e.g. faulty LED). The controlled current limit circuit
prevents large inductor current spikes, even at start-up.
To avoid possible leakage currents, the EN control pin
disconnects the LEDs from ground during shutdown.
The CM9330 is available in a compact TQFN-16 packages. It can operate over the industrial temperature
range of -40°C to 85°C.
Typical Application
VIN 2.7V to 6.0V
CIN
on (by default)
10 uF/10V
off
1 ISET1
Enable
D1
4.7 uH
1A, 20V
VOUT
COUT
1 uF/16V
13
EN
14
NC
RSET1
15
NC
NC
16
L1
VOUT
CH1
12
Channel
CH2 CH3
22K
ISET2
MODE
VIN
4
22K
GND
LED3
RSET2
CM9330
NC
SW
ISET3
3
PhotonICTM
LED1
LED2
2
5
6
7
8
RSET3
11
10
9 interlv ( by default)
no-interlv
22K
© 2006 California Micro Devices Corp. All rights reserved.
04/26/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
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Tel: 408.263.3214
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Fax: 408.263.7846
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www.cmd.com
1
PRELIMINARY
CM9330
Package Pinout
PACKAGE / PINOUT DIAGRAM
7 LED3
8 VIN
11 SW
14
13
12 VOUT
EN
1
NC
2
ISET1
10 GND
15
LED1
9 NC
TQFN16
4 X4
16
3
NC
4
NC
ISET2
MODE
6 ISET3
5 LED2
Bottom View
16-Lead TQFN Package
(4mm x 4mm)
Note: This drawing is not to scale.
Ordering Information
PART NUMBERING INFORMATION
Lead Free Finish
Pins
Package
Ordering Part Number1
16
TQFN
CM9330-01QE
Part Marking
Note 1: Parts are shipped in Tape & Reel form unless otherwise specified.
Specifications
ABSOLUTE MAXIMUM RATINGS
PARAMETER
RATING
UNITS
±2
kV
VIN to GND
[GND - 0.3] to +6.0
V
Pin Voltages
VOUT, SW to GND
LED1, LED2, LED3 to GND
ISET1, ISET2, ISET3 to GND
20
20
[GND - 0.3] to +5.0
V
V
V
Storage Temperature Range
-65 to +150
°C
Operating Temperature Range
-40 to +85
°C
300
°C
ESD Protection (HBM)
Lead Temperature (Soldering, 10s)
© 2006 California Micro Devices Corp. All rights reserved.
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04/26/06
PRELIMINARY
CM9330
Specifications (cont’d)
ELECTRICAL OPERATING CHARACTERISTICS (SEE NOTE 1)
VIN = 3.6V; CIN = 10μF, COUT = 1μF, L1 = 4.7μH, interleave mode, TA = 25°C (unless otherwise specified)
SYMBOL
PARAMETER
VIN
Input Voltage Range
IQ
Quiescent Current
CONDITIONS
MIN
VUVLO
Undervoltage Lockout
VOVP
Output Overvoltage Protection
VOUT Rising
ISD
Shutdown Current
VEN = 0V
VEN
Device Enable Threshold
Device ON (by default)
Device OFF
mA
2.2
2.4
V
19.5
20.0
V
15
μA
0.2
V
V
35
mA
1.2
2.0
19.0
10
VIN = 3.0V to 6.0V, RSET1(kΩ)
4 WLED
2
Number of LEDs (Note 2)
VIN = 2.7V to 6.0V
1
VLED1
Voltage on LED1 Pin
Standard load (Note 3)
Channel 2
ILED2
LED Current (Note 1)
VIN = 3.0V to 6.0V, RSET2(kΩ)
4 WLED
2
Number of LEDs (Note 2)
VIN = 2.7V to 6.0V
1
VLED2
Voltage on LED2 Pin
Standard load (Note 3)
Channel 3
ILED3
LED Current (Note 1)
VIN = 3.0V to 6.0V, RSET3(kΩ)
4 WLED
2
Number of LEDs (Note 2)
VIN = 2.7V to 6.0V
1
Voltage on LED3 Pin
Standard load (Note 3)
Boost Circuit (Note 3)
ΔILED / ILED ⋅ ΔVIN Line Regulation
MAX
1.0
LED Current (Note 1)
VLED3
2.0
2.7
ILED < 0.6mA (each channel), nonswitching
VIN Rising
Channel 1
ILED1
6.0
UNIT
S
V
TYP
450
--------------R SET1
5
0.80
450
--------------R SET2
V
30
mA
5
0.80
450
--------------R SET3
V
30
mA
5
VIN = 3.0V to 6.0V Each Channel
0.80
V
1
%/V
IOUT
Boost Output Current
VIN = 3.0V to 6.0V
100
VOUT
Boost Output Voltage
ILED 1,2,3 = 2mA to ILED MAX
VIN
20
V
Duty Cycle Range
VIN = 2.7V to 6.0V,
ILED 1,2,3 = 2mA to ILED MAX
5
95
%
VOUTR
Output Voltage Ripple
Standard Load (Note 3)
50
RDSON
MOSFET ON Resistance
ISW = 0.8A, VGS = 15V
300
Eff
Efficiency
Standard Load (Note 3)
85
ISW
Switch Peak Current
Standard Load (Note 3)
0.65
A
PIN
Input Power
ILED 1,2,3 = 20mA, 4WLED+1W+1W
835
mW
Channel Current Matching
(Note 4)
1% RSET Accuracy, Each Channel
3
%
D
Control
ILED acc
mA
mVpp
500
mΩ
%
© 2006 California Micro Devices Corp. All rights reserved.
04/26/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
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Tel: 408.263.3214
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Fax: 408.263.7846
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3
PRELIMINARY
CM9330
Specifications (cont’d)
ELECTRICAL OPERATING CHARACTERISTICS (SEE NOTE 1)
VIN = 3.6V; CIN = 10μF, COUT = 1μF, L1 = 4.7μH, interleave mode, TA = 25°C (unless otherwise specified)
SYMBOL
PARAMETER
CONDITIONS
ILEDR
LED Current Ripple
Standard Load (Note 3)
ILEDNL
No-Load Mode (Note 5)
All Channels
Switching Frequency
VIN = 2.7V to 6.0V
fs
MIN
TYP
MAX
0.2
0
0.8
1.0
UNIT
S
mApp
0.6
mA
1.2
MHz
VIN = 3.6V; CIN = 10μF, COUT = 1μF, L1 = 4.7μH, non-interleave mode (Note 6), TA = 25°C (unless otherwise specified)
SYMBOL
ILED
ΔILED / ΔVIN
PIN
PARAMETER
CONDITIONS
LED Current
VIN = 3.0V to 6.0V, RSET(kΩ)
Line Regulation @ High Load
L = 4.7μH, VIN = 3.0V to 5.5V
4W+4W+4W, 40mA+40mA+40mA
L = 10μH, VIN = 3.0V to 5.5V
4W+4W+4W, 60mA+40mA+40mA\
ILED 1,2,3 = 20mA, 4WLED+1W+1W
Input Power
MIN
TYP
MAX
2
730-----------R SET
IMAX
UNIT
S
mA
1
%/V
3
%/V
975
mW
Note 1: ILED is the average PWM current through the LED string with internal 2/3 duty cycle and a 6 ms period. The following formula must be used to calculate the LED current:
I LED ( mA )
450
= --------------------R
SET ( kΩ )
Note 2: For lower LED forward voltage the number of LEDs can be increased up to the maximum output voltage limit.
Note 3: Standard Load is a 4 series x 3 parallel configuration set for IsetLED = 20 mA each channel (RSET1,2,3 = 22 kΩ).
Generally, a "4W+1W+1W" like formula denotes the WLED number of each channel, i.e. CH1+CH2+CH3 configurations.
Note 4: [ILED(set) - ILED(effective)] / ILED(set) for each channel.
Note 5: A LED current value below 0.6 mA for each channel set the circuit in No-load mode; all channels and MOSFET switch are in
shutdown and DC circuit current consumption is limited to 1 mA (see quiescent current).
Note 6: For non-interleave mode, all parameters have the same min/typ/max interleave mode values, unless otherwise specified.
© 2006 California Micro Devices Corp. All rights reserved.
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490 N. McCarthy Blvd., Milpitas, CA 95035-5112
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Tel: 408.263.3214
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PRELIMINARY
CM9330
Typical Performance Curves
ILED vs. VIN (high current)
ILED vs. VIN
21.2
160
21.0
ILED1+IED2+ILED3 (mA
ILED2
20.6
ILED (mA)
150
ILED1
20.8
20.4
20.2
20.0
19.8
ILED3
19.6
Interleave
L = 4.7uH
4 WLED/ch
TA = 25 ºC
19.4
19.2
19.0
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
L=10uH, 3W+4W+4W, 60mA+40mA+40mA
140
L=10uH, 4W+4W+4W, 60mA+40mA+40mA
130
L=10uH, 4W+4W+4W, 40mA+40mA+40mA
120
L=4.7uH, 4W+4W+4W, 40mA+40mA+40mA
110
100
L=4.7uH, 4W+4W+4W, 35mA+30mA+30mA
90
80
No-Interleave
TA = 25 ºC
70
6.0
2.0
2.5
3.0
3.5
V IN (V)
4.0
4.5
5.0
5.5
6.0
V IN (V)
EFFICIENCY v.s VIN
EFFICIENCY vs. ILED
90
90
Vin=5.6V
85
Efficiency (%
Efficiency (%
85
80
Interleave
ILED1,2,3 = 20mA
L = 4.7uH
4 WLED/ch
2.5
3.0
3.5
4.0
4.5
5.0
5.5
80
75
70
65
L = 4.7uH
4 WLED/ch
TA = 25 ºC
60
75
2.0
4.2V
3.6V
3.0V
2.7V
0
6.0
5
10
15
V IN (V )
20
25
30
35
ILED (m A)
EFFICIENCY vs. INDUCTOR
EFFICIENCY vs. STRING CONFIGURATION
90
90
L=4.7uH
88
L=3.3uH
L=2.7uH
80
75
ILED=20mA+20mA+20mA
86
L=1.5uH
Efficiency (%
Efficiency (%
85
L=10uH
L=15uH
84
ILED=5mA+10mA+20mA
82
ILED=20mA+10mA+5mA
80
78
Interleave
L = 4.7uH
CH1,2,3 = 4W+3W+2W
TA = 25 ºC
70
ILED1,2,3 = 20 mA
4 WLED/ch
TA = 25 ºC
76
74
65
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
2.0
2.5
V IN (V )
3.0
3.5
4.0
4.5
5.0
5.5
6.0
V IN (V )
© 2006 California Micro Devices Corp. All rights reserved.
04/26/06
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PRELIMINARY
CM9330
Functional Block Diagram
VIN
VOUT
UVLO
BIAS
OSC
BG
EN
OVP
PMW
LOGIC
D4
ENABLE
R
ISET1
LED1
D1
ISET2
SW
Q4
Q1
LED2
D2
CONTROL
Q2
LED3
ISET3
D3
Q3
MODE
CM9330
GND
Pin Descriptions
PIN DESCRIPTIONS
LEAD(s)
NAME
DESCRIPTION
1
ISET1
Channel 1 LED current set pin. Between this pin and GND connect the RSET1 resistor, calculated as follows:
450 R SET1 ( kΩ ) = ---------------------------I LED1 ( mA )
where ILED1 is the DC LED current in channel 1.
2
LED1
3
NC
4
ISET2
Pin to cathode of channel 1 LED string.
Not internally connected. For better heat flow, connect to GND.
Channel 2 LED current set pin. Between this pin and GND connect the RSET2 resistor, calculated as follows:
450 R SET2 ( kΩ ) = ---------------------------I LED2 ( mA )
where ILED2 is the DC LED current in channel 2.
5
LED2
Pin to cathode of channel 2 LED string.
© 2006 California Micro Devices Corp. All rights reserved.
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PRELIMINARY
CM9330
Pin Descriptions (cont’d)
PIN DESCRIPTIONS
6
ISET3
Channel 3 LED current set pin. Between this pin and GND connect the RSET3 resistor, calculated as follows:
450 R SET3 ( kΩ ) = ---------------------------I LED3 ( mA )
where ILED3 is the DC LED current in channel 3.
7
LED3
Pin to cathode of channel 3 LED string.
8
VIN
9
MODE
Input supply voltage pin. Bypass with a 10 µF or larger ceramic capacitor to ground.
10
GND
11
SW
12
VOUT
Output voltage pin, which connects to the anodes of all LEDs. Bypass with a 1.0 µF or greater
ceramic capacitor to ground for low output ripple voltage.
13
EN
Enable pin. The circuit is ON when VEN is above 1.0V. The circuit is OFF when VEN is below
0.2V. Active High (ON) by default.
14
NC
Not internally connected. For better heat flow, connect to GND.
15
NC
Not internally connected. For better heat flow, connect to GND.
16
NC
Not internally connected. For better heat flow, connect to GND.
EPad
GND
When MODE is HIGH (default), the circuit uses interleave mode. When MODE is LOW
(GND), the circuit uses non-interleave mode.
Ground terminal pin.
Switching node. Internally connected to the drain of the integrated switch.
Ground; backside exposed pad.
Application Information
The CM9330 is a high efficiency, constant frequency
current regulating boost driver ideally suited for driving
white LEDs to backlight LCD color displays and a camera flash in Li-ion powered portable devices. The
CM9330 is the perfect driver for portable applications
such as cellular phones, digital still cameras, PDAs,
and any application where small space, compact overall size, and low system cost, are critical.
With a maximum 140mA/19V output capability, the circuit can drive up to 15 WLEDs (5 series x 3 parallel)
allowing up to 35 mA per channel. It includes a switch
and an internally compensated loop for regulating the
current into the LEDs. The CM9330 delivers a constant
current to series-connected LEDs, ensuring uniform
brightness and color purity regardless of any LED forward voltage variations.
The proprietary design architecture allows asymmetrical loading on each channel and maintains high efficiency (typ 85%) at low VIN resulting in longer battery
life, and cool, reliable operation when an adapter is
supplying high VIN. The maximum LED current for
each channel is independently programmed with external low power resistors avoiding ballast resistors.
An 1MHz constant frequency PWM scheme saves
board space using of small, low cost external components , allowing designers to avoid sensitive IF bands
in RF applications. The circuit operates with low value
inductor and low value output ceramic capacitor keeping voltage and current ripple in 1% range.
The output over-voltage protection circuit prevents
damage in the case of a high impedance output (e.g.
faulty LED). The controlled current limit circuit limit prevents large inductor current spikes, even at start-up. To
avoid possible leakage currents the EN control pin disconnects the LEDs from ground during shutdown.
CM9330 Operation
When a voltage that exceeds the undervoltage lockout
threshold (UVLO) is applied to the VIN pin, the
CM9330 initiates a softstart which limits the inrush current while the output capacitors are charged. Following
© 2006 California Micro Devices Corp. All rights reserved.
04/26/06
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7
PRELIMINARY
CM9330
Application Information (cont’d)
softstart, the CM9330's internal NMOS drives an external inductor and Schottky diode delivers the inductor's
stored energy to the load.
Setting the LED Current
The output current is set by the value of the RSET connected between the ISET pin and GND, according to
the equations:
450 R SET ( kΩ ) = ------------------------I LED ( mA )
(a) Interleave
730
R SET ( kΩ ) = -------------------------I LED ( mA )
(b) Non-interleave
PWM Brightness Control
The brightness WLEDs level can be continuously controlled for each channel using a PWM signal in 1-50
KHz range (recommended value is 10 kHz). As an
example the PWM signal can be applied directly
through RSET resistor for negative slope or by using a
switch transistor for positive slope. See Figure 1 for different brightness control methods and results.
The inductor is used to store energy in a boost converter. The amount of energy stored in the inductor and
transferred to the load is controlled by the PWM. The
inductor is operated in the discontinuous conduction
mode, and to assume proper operation, the inductor
value must be limited to a maximum value.
An inductor with low series resistance (DCR)
decreases power losses and increases efficiency. The
core material should be capable of operating at I MHz
with minimal core losses. An inductance of 4.7-µH is
optimum for most applications, but low DCR inductor
values in 1.5-15uH range are also recommended for
high efficiency applications.
To ensure proper operation of the current regulator
over a wide range of conditions, the inductor should be
selected based on the required load power and the
minimum input voltage. The saturation current rating
should be chosen well above the steady state peak
inductor current. At minimum VIN and full duty cycle
(worse case), this is approximately:
1
V IN ( MIN ) × t ON 3V × 0.95 × --------------1MHz
I PEAK ≅ --------------------------------------- ≅ ----------------------------------------------- ≅ 0.7A
L
4.7μH
RSET1
PWM
signal
Inductor Selection
ISET1
22k
RSET2
ISET2
Diode Selection
36k
RSET3
The low forward voltage and fast switching time make
Schottky diodes the choice for high efficiency operation. Make sure the diode has a reverse voltage rating
greater than the maximum output voltage. The diode
conducts only when the power switch is on, so a peak
current rating above 1A should be sufficient for a typical design.
ISET3
91k
CM9330
(a) Schematic
25
ILED1
negative slope
20
ILED2
ILED (mA)
Capacitor Selection
15
For proper performance, use surface-mount, low ESR
ceramic capacitors for CIN and COUT. X7R or X5R
ceramic dielectric provides good stability over the operating temperature and voltage range.
10
ILED3
positive slope
5
0
0
10
20
30
40
50
60
70
80
90
In most LED applications, high frequency output ripple
is not a concern because it will not cause intensity variations that are visible to the human eye.
100
DUTY (%)
(b) Brightness Curves
Figure 1. Brightness Control Using
Different Methods
© 2006 California Micro Devices Corp. All rights reserved.
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04/26/06
PRELIMINARY
CM9330
Application Information (cont’d)
For such applications, when low ripple is needed, a
22μF input capacitor and/or 2.2 μF output capacitor are
recommended.
REF
DES
CIN
COUT
L1
D1
DESCRIPTION
Capacitor, 10μF,
10V, Ceramic, 1206
Capacitor, 1μF, 16V,
Ceramic, 0805
Inductor, 4.7μH, 1A,
Low DCR
Schottky Diode, 1A,
20V, SMD
SOURCE
Murata, GRM319R61A106KE19D
Vishay, VJ1206G106KXQ
Murata, GRM188R61C105KA93D
TDK, C2012X5R1C105K
Coilcraft, LP06013-472ML
TMP Electronics Co., SPC-03802-4R7
CHILISIN, SCD03015-4R7
SUMIDA, CDH3D13/S4R7
IR, MBRS120
CHENMKO, SSM5817S
Input Filter
If CM9330 is more than 4" from main power supply
point, use an input RC filter to avoid high ripple and
input transients to the circuit input pin (see Figure 2).
In this case, because of small input ripple, the efficiency is about 2% higher.
Layout Guide
Components should be placed ase close as practical to
the IC to assure good performance. The input and output capacitors should be close, with minimum trace
resistance and inductance. Reflected input ripple
depends on the impedance of the VIN source, such as
the PCB traces and the Li-ion battery, which has elevated impedance at higher frequencies. The input
capacitor located near the converter input reduces this
source impedance and ripple. Any ESR from the
capacitor will result in steps and spikes in the ripple
waveform, and possibly produce EMI.
Route any noise sensitive traces away from the switching power components. Place the inductor and diode
as close as possible to the SW pin to prevent noise
emissions.
The ground connections for RSET(1,2,3) resistors
should be kept separate from the high power grounds
and connect directly to the ground pin to assure accurate current and voltage settings. For better heat flow,
connect all NC pins to GND plane. Also connect the
thermal landing to the bottom ground plane with thermal vias.
to VIN
7
GND
MODE
VIN
LED3
CM9330
10
9
RF
100
8
CF
0.1 uF/10V
Figure 2. Input Filter Solution
Mode Selection
Two working modes are available for CM9330: interleave mode (output voltage is periodically adjusted
depending on each channel load) and non-interleave
mode (same output voltage level for all channels). For
interleave option, keep MODE pin floating (HIGH by
default) and for non-interleave option, connect MODE
pin to GND.
Figure 3. Example CM9330 PC Layout and
Component Placement for Standard Application
© 2006 California Micro Devices Corp. All rights reserved.
04/26/06
490 N. McCarthy Blvd., Milpitas, CA 95035-5112
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Tel: 408.263.3214
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Fax: 408.263.7846
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9
PRELIMINARY
CM9330
Mechanical Details
TQFN-16 Mechanical Specifications
Mechanical Package Diagrams
The CM9330 is supplied in a 16-lead, 4.0mm x 4.0mm
TQFN package. Dimensions are presented below.
For complete information on the TQFN16, see the California Micro Devices TQFN Package Information document.
D
Package
TQFN-16 (4x4)
Leads
16
Millimeters
Min
A
A1
A3
b
Nom
Max
0.80
0.84
0.00
0.04
Min
Nom
Max
0.031
0.033
0.15 C
0.002
0.15 C
0.00
0.20 REF
0.25
.008
0.33
0.010
D
4.0 BSC
0.157
1.95 REF
0.077
E
0.08 C
0.077
2.15
0.081
0.65 TYP.
0.55
0.085
0.157
1.95 REF
2.05
e
L
0.081
4.0 BSC
E1
E2
2.15
0.10 C
A3 A1
SIDE VIEW
0.085
A
0.026
0.65
0.022
# per
tube
xx pieces*
# per
tape and
reel
xxxx pieces
D1
0.026
E1
2.05
TOP VIEW
0.013
D1
D2
Pin 1 Marking
Inches
E2
Dim.
E
PACKAGE DIMENSIONS
Controlling dimension: millimeters
D2
* This is an approximate number which may vary.
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.
10 490 N. McCarthy Blvd., Milpitas, CA 95035-5112
l
Tel: 408.263.3214
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Fax: 408.263.7846
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www.cmd.com
04/26/06