NPC SM8132A

SM8132A
White LED Driver IC
OVERVIEW
The SM8132A is a charge pump DC/DC converter that switches between ×1 and ×1.5 automatically. The
SM8132A switches between ×1 and ×1.5 according to detected LED drive current, so that the battery life can
be prolonged to the fullest extent. Since the connected LED are all detected for the switching, the SM8132A
can respond to the variation of LED forward voltage. 4-channel of LED drive current control circuit is built-in,
the SM8132A can control 1 to 4 lights of white LED, which are connected in parallel. The LED drive current
per channel is set up by external resistor. Besides, the input signal controlling of EN pin allows ON/OFF and
dimming.
FEATURES
■
■
■
■
■
■
■
Battery life extension by automatic charge pump
switch between ×1 and ×1.5 according to the
detection of the LED drive current
Controlling 1 to 4 lights of white LED connected
in parallel
Set up LED drive current value by external resistor
(5kΩ:5mA/ch, 15kΩ:15mA/ch, 20kΩ:20mA/ch)
1-wire input controlling
ON/OFF and brightness control by input signal
controlling of EN pin
Soft start circuit built-in
Thermal shut down circuit built-in
■
■
■
■
■
■
■
■
Supply voltage range
• No-load current (IOUT = 0mA): 2.7 to 4.6V
• Load current (IOUT = 80mA): 3.3 to 4.6V
Maximum output voltage: 4.2V (typ)
Maximum output current: 80mA (typ)
Quiescent current
• Not-switching (×1 mode): 0.3mA (typ)
• Switching (×1.5 mode): 1.0mA (typ)
Standby current (Power save mode): 0.01µA (typ)
Operating frequency (×1.5 mode): 750kHz (typ)
LED drive current matching (RSET = 20kΩ):
± 3%
Package: 16-pin QFN
WL-CSP (under development)
APPLICATIONS
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■
■
■
■
■
Cellular phone
PDA
Portable games
Handy terminal
Digital still camera
Digital video camera
LCD back light
White LED driving
ORDERING INFORMATION
Device
Package
SM8132AB
16-pin QFN
SM8132AW
WL-CSP
NIPPON PRECISION CIRCUITS INC.—1
SM8132A
PACKAGE DIMENSIONS
(Unit: mm)
QFN-16
TOP VIEW
3.0 ± 0.08
BOTTOM VIEW
1.8
1.8
0.3 ± 0.1
0.5
3.0 ± 0.08
A
3 = 1.5 ± 0.05
B
C 0.3
φ 0.05 M S A B
0.05 S
0.5
0.7 ± 0.05
0.2 S
0.2 ± 0.05
S
0.1 ± 0.05
0.02 S A B
0.22 ± 0.05
WL-CSP (under development)
TBD
NIPPON PRECISION CIRCUITS INC.—2
SM8132A
PINOUT
(Top view)
WL-CSP (under development)
GND
ISET
DIN3
NC
QFN-16
EN
DIN4
NC
VIN
TBD
PGND
VOUT
C2M
C2P
DIN2
DIN1
C1P
C1M
PIN DESCRIPTION
Number
Name
I/O
–
PGND
–
Charge pump ground connection
2
–
VOUT
O
LED drive voltage output
3
–
C2M
–
Charge pump capacitor connection 2M
4
–
C2P
–
Charge pump capacitor connection 2P
5
–
VIN
–
Voltage supply
6
–
NC
–
No connection
7
–
DIN4
O
LED drive current control output 4 (connect to ground when not used)
QFN-16
WL-CSP
1
Description
8
–
EN
Ip*1
9
–
NC
–
No connection
10
–
DIN3
O
LED drive current control output 3 (connect to ground when not used)
11
–
ISET
I
LED drive current setting resistor connection
12
–
GND
–
Ground
13
–
DIN2
O
LED drive current control output 2 (connect to ground when not used)
14
–
DIN1
O
LED drive current control output 1 (connect to ground when not used)
15
–
C1P
–
Charge pump capacitor connection 1P
16
–
C1M
–
Charge pump capacitor connection 1M
Enable data input (High active)
*1. Ip: Input with built-in pull-down resistor
NIPPON PRECISION CIRCUITS INC.—3
SM8132A
BLOCK DIAGRAM
C1M C1P C2M C2P
Charge pump
1 /1.5
VIN
VOUT
DIN1
Mode control
&
Output voltage control
&
Protection
DIN2
Current
control
&
Current
detect
TSD
DIN3
DIN4
EN
Control
logic
ISET
GND
PGND
NIPPON PRECISION CIRCUITS INC.—4
SM8132A
SPECIFICATIONS
Absolute Maximum Ratings
GND = 0V
Parameter
Symbol
Rating
Unit
VIN voltage range
VIN
−0.3 to 5.5
V
Input voltage range
VEN
VGND – 0.3 to VIN + 0.3
V
VDIN1 to 4
VGND – 0.3 to VIN + 0.3
V
VOUT
5.5
V
IOUT
500
mA
PD
800 (Ta = 25°C)*1
mW
TJMAX
+125
°C
Tstg
−55 to +125
°C
Output voltage range
VOUT output current
Power dissipation
Junction temperature
Storage temperature range
*1. When mounted on a 4-layer PCB.
Note. The device may suffer breakdown if any one of these parameter ratings is exceeded.
800
Power dissipation [mW]
800
640
600
480
400
320
200
0
25
35
45
55
65
75
85
Operating temperature [°C]
Recommended Operating Conditions
GND = 0V
Rating
Parameter
Supply voltage range
Pin
VIN
Symbol
Conditions
Unit
min
typ
max
VIN0
×1.0 mode, IOUT = 0mA
2.7
3.6
4.6
V
VIN
×1.5 mode, IOUT = 80mA
3.3
3.6
4.6
V
Each logic-level pin
0
−
VIN
V
−30
−
+85
°C
Input voltage range
EN
VES
Ambient temperature range
−
Ta
NIPPON PRECISION CIRCUITS INC.—5
SM8132A
Electrical Characteristics
VIN = 3.6V, GND = 0V, Ta = 25°C unless otherwise noted.
Rating
Parameter
Pin
Standby current
VIN
Quiescent current
VIN
Symbol
Condition
Unit
min
typ
max
ISTB
Power-save mode
–
0.01
1.00
µA
IDD1
×1.0 mode, IOUT = 0mA
–
0.3
1.0
mA
IDD2
×1.5 mode, IOUT = 0mA
–
1.0
3.0
mA
Output voltage
VOUT
VOUT
×1.5 mode, IOUT = 80mA
4.0
4.2
4.4
V
Maximum output current
VOUT
IOUT
×1.5 mode
80
–
–
mA
Operating frequency
C1M
fOSC
×1.5 mode switching frequency
650
750
850
kHz
EN
TPOR
Time from when power is applied
until internal circuits reset
–
0.05
1.00
ms
Soft start time
DIN1 to 4
TSS
EN startup → ILED rising edge
–
1.3
5.0
ms
LED drive pin leakage current
DIN1 to 4
Ileak1 to 4
Power-save mode, DIN pin = 4.2V
–
0.01
1.00
µA
LED drive current
DIN1 to 4
ILED1 to 4
×1.0 mode, RSET = 20kΩ
19.0
20.0
21.0
mA
LED drive current matching
DIN1 to 4
∆ILED
×1.0 mode, matching between
channels with ILED maximum setting
–3.0
–
+3.0
%
LED drive pin voltage
DIN1 to 4
VDIN1 to 4
×1.0 mode, RSET = 20kΩ
–
160
–
mV
ISET
RSET
RSET maximum value
–
–
50
kΩ
Input signal frequency*1
EN
fENIN
EN input pulse duty 50%,
maximum signal input frequency
–
–
150
kHz
Input pulse width*1
TENH
Minimum EN pulse HIGH-level width
3.0
–
–
EN
µs
TENL
Minimum EN pulse LOW-level width
3.0
–
–
µs
TCEH
Time from when EN = LOW until LED
drive circuit shutdown
1.17
1.37
1.63
ms
VIH
HIGH-level input voltage range
1.8
–
–
V
VIL
LOW-level input voltage range
–
–
0.6
V
IIH
Pull-down pin, EN pin = 3.6V
–
5.0
10.0
µA
IIL
EN pin = 0V
–1.0
–
–
µA
Internal power-ON reset time*1
LED drive current
setting resistance*1
Hold time
EN
Input voltage
EN
Input current
EN
*1. Design guaranteed value
NIPPON PRECISION CIRCUITS INC.—6
SM8132A
VOUT Efficiency
100
VOUT efficiency [%]
90
80
VF = 3.2V
70
VF = 3.4V
VF = 3.6V
60
50
3.2
VF = 3.8V
3.4
3.6
3.8
4.0
VIN [V]
4.2
4.4
4.6
4.4
4.6
Efficiency of PIN vs. POUT
(LED × 4pcs, ILED = 20mA, IOUT = 80mA)
100
VOUT efficiency [%]
90
80
VF = 3.2V
70
VF = 3.4V
VF = 3.6V
60
50
3.2
VF = 3.8V
3.4
3.6
3.8
4.0
VIN [V]
4.2
Efficiency of PIN vs. POUT
(LED × 3pcs, ILED = 15mA, IOUT = 45mA)
NIPPON PRECISION CIRCUITS INC.—7
SM8132A
FUNCTIONAL DESCRIPTION
LED Drive Current Setting
The SM8132A LED drive current setting is controlled by the combination of resistance connected to ISET and
the EN input signals.
(1) Setting LED Drive Current using RSET
The maximum drive current per LED (when DATA = 1) is determined by the external resistance connected to
ISET. For example, if ILED MAX = 15mA, from the graph below, a resistance “RSET” of 15kΩ should be connected between ISET and GND. Note that while RSET can have a maximum resistance 50kΩ, the total LED
output current must not exceed the maximum output current of 80mA.
50
ISET
ILED [mA]
40
RSET
30
20
10
0
0
GND
10
20
30
40
50
RSET [kΩ]
LED drive current maximum setting using RSET
(2) Setting LED Drive Current using EN Input Signals
The EN input ENABLE/DISABLE circuit, also simultaneously counts the number of input pulses using an
internal counter and adjusts the LED drive current setting in response. The internal 4-bit counter provides 16step (DATA = 1 to 16) adjustment, where each step is 1/15th of the maximum current (ILED MAX) set by RSET.
On the 16th pulse (DATA = 16), the LED drive current control circuit shuts down. On the 17th pulse (DATA =
1), the LED drive current is reset to the maximum current value. As the current is set to the maximum value on
the first pulse, applications without pulse input can also be employed (by controlling brightness using RSET).
RSET=10kΩ
RSET=15kΩ
RSET=20kΩ
EN
25
123
ILED [mA]
20
EN input
pulse
15
10
5
0
0
GND
4
8
12
16
DATA set by EN input pulse
LED drive current setting variation using EN input
pulse modulation
Table. LED drive current setting and EN input pulse count
DATA
EN
pulse
count
ILED
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
15/15
14/15
13/15
12/15
11/15
10/15
9/15
8/15
7/15
6/15
5/15
4/15
3/15
2/15
1/15
0
NIPPON PRECISION CIRCUITS INC.—8
SM8132A
EN input signal and LED drive current setting (startup)
An internal startup signal goes HIGH on the first rising edge of EN, and LED drive current starts after the softstart time expires. The LED drive current control circuit sets the current by counting the input pulses on EN,
hence the EN input voltage must be switched HIGH → LOW → HIGH the required number of data steps to
reduce the current setting. When the desired setting is reached, the EN input voltage should be tied HIGH to
maintain the setting. Note that the LED drive current does not flow when EN is LOW.
The EN data input circuit operates during the soft-start time when no LED drive current flows, hence the current setting can be adjusted during the soft-start time and the LED drive circuit will then start at the desired current setting. However, setting the current using EN signal pulses is possible only when the power-ON reset
ends after a rising edge on the VIN supply. Consequently, a delay of 1ms or greater should be allowed after
VIN is applied before starting the EN input signals.
EN
input signal
ILED 1 to 4
1
1
2
2
3
4
3
5
4
6
5
7
6
8
7
8
EN input signal and LED drive current setting
■
The LED drive current is set by the number of EN input signal rising-edge. The LED drive current control
circuit is disabled, and the LED drive current does not flow during EN input signal LOW interval or at startup until after the soft-start time expires.
EN input signal and LED drive current setting (disable interval)
The LED drive current setting due to EN input is set by the 4-bit counter (16 steps). On the 17th pulse, the
counter DATA = 1 and the current is reset to the maximum current value. When the counter DATA = 16, ILED =
0mA and the LED drive circuit shuts down.
EN input
11 12 13 14 15 16 17 18 19 20 21
ILED
disable signal
ILED
off
1
ILED 1 to 4
11 12 13 14
2
3
4
5
15 16
LED drive current setting disable interval
When EN is held LOW for an extended interval, the internal enable signal “CE” goes LOW and the device
enters power-save mode. In this mode, the EN input internal counter is reset and subsequent rising-edge pulses
on EN restart the counter from DATA = 1.
NIPPON PRECISION CIRCUITS INC.—9
SM8132A
VOUT Output Circuit Mode Switching
The SM8132A switches between 3 output states: power-save mode (standby state), ×1.0 mode (VIN through
mode), and ×1.5 mode (×1.5 charge pump boost). This automatically adjusts the VOUT output to match the
drive LED characteristics and reduces the total power dissipation. Switching to and from ×1.0 and ×1.5 mode
occurs automatically in an internal circuit, and cannot be controlled using an external input.
Power-ON internal reset time
The SM8132A switches from standby condition (power-save mode) to normal operating condition (×1.0/×1.5
mode) on the first rising edge of EN. Note that if the VIN supply voltage is applied when EN is HIGH, startup
occurs after the internal power-ON reset time (approximately 50µs) expires. At startup, operation commences
in ×1.5 mode for a fixed interval during the soft-start time in order to determine whether a LED is connected to
each DIN pin.
VIN
power source
(1)
VIN
Power on
reset output
POR time
typ: 50µs
(2)
Soft start time
Internal
enable (CE)
(3)
Power save
mode
1.5 mode
Power-ON reset operation
(1) VIN voltage rises when power is applied.
(2) Power-ON reset (POR) circuit resets internal circuits approximately 50µs after the power is applied.
(3) If EN is HIGH when power is applied, the internal circuits start operating when the internal “CE” signal
rising edge occurs after the power-ON reset time. If EN is LOW when power is applied, the “CE” rising
edge occurs simultaneously with the first rising edge.
EN
input signal
LED current
EN
(1)
Dimming pulses enable
Soft start time
typ: 1.3ms
LED ON
(2)
Soft start time and LED current
(1) If the EN signals are input after POR time is expired, the soft start time begin from the first EN input rising
edge. The current setting can be adjusted during the soft-start time.
(2) LED current starts flow immediately before the soft start time expires.
NIPPON PRECISION CIRCUITS INC.—10
SM8132A
Switching to power-save mode
The internal circuit operating mode switches from ×1.0/×1.5 mode to power-save mode when EN goes LOW
and do not switch HIGH for an interval of 1.63ms (max). This function turns the LEDs OFF and automatically
transfers internal circuit control to power-save mode, suppressing current consumption.
EN
Internal
enable (CE)
Power
save
1.0 or 1.5
CE hold time 1.63ms (max)
Power
save
EN input signal and internal enable signal “CE”
■
If the EN input signal is held for an interval greater than the “CE” hold time 1.63ms (max), the SM8132A
switches to power-save mode. The internal circuits are reset on the “CE” falling edge, and the current setting
must be re-established before restart.
Switching from ×1.0 mode to ×1.5 mode
If the LEDs can be driven solely by the current determined by RSET and EN pulse input without boosting the
VIN input voltage, the VOUT output operates in ×1.0 mode. In other words, if sufficient current flows even with
the LED forward-direction voltage drop “VF”, then VOUT is less than 4.2V. Operation in the more efficient
×1.0 mode reduces the total power dissipation and extends the battery drive time. And if low “VF” LEDs are
used or the LED drive current setting is LOW, the operating time in ×1.0 mode is also extended.
1.0 mode
(high efficiency)
1.5 mode
(low efficiency)
1.0 mode
(high efficiency)
1.5 mode
(low efficiency)
High VF LED
Low VF LED
High
VIN input
Low
VOUT mode switching time comparison due to drive LED “VF” variation
If the VIN voltage falls or RSET increases such that the LED drive current is too low in ×1.0 mode, then the
LED drive circuit low-current detector operates, the VOUT output is automatically switched to ×1.5 mode, and
the charge pump boosts the output voltage. This occurs even if only one LED low-current condition is detected
among the 4-channel LED drive circuits, thus it is recommended that LEDs have small “VF” variation to optimize the total efficiency.
NIPPON PRECISION CIRCUITS INC.—11
SM8132A
VIN
input voltage
1.0
Low ILED
detector
1.5 threshold
(1)
Low ILED
detected
VOUT mode
(2)
1.0 mode
1.5 mode
4.2V
VOUT
output voltage
(3)
VIN voltage drop and VOUT output voltage
(1) When VIN falls, VOUT cannot overcome the LED “VF” rating, causing insufficient current flows and the
ILED low-current signal becomes active.
(2) When the ILED low-current condition is detected, the VOUT output circuit switches to ×1.5 mode (charge
pump mode).
(3) Prior to switching to ×1.5 mode, the VOUT voltage may be lower than 4.2V but sufficient current is supplied to the LED.
If after startup, the LED connected to a DIN pin is switched, the LED connection detector circuit flags an error,
and correct mode switching may not occur. If the DIN pin does not control the LED drive current, the low-current detector does not operate and the device cannot switch to ×1.5 mode.
NIPPON PRECISION CIRCUITS INC.—12
SM8132A
Switching from ×1.5 mode to ×1.0 mode
VF increases immediately after the LED current starts to flow, and then decreases as the LED temperature
increases due to the heating effect of the current flow. It can take about 10 seconds for the LED temperature to
stabilize and for VF to reach equilibrium, and VF may fluctuate more than 200mV. The VF fluctuation is
affected by the ambient temperature and LED current setting, and has a large affect on the automatic mode
switching voltage tolerances. To counter the effects of VF fluctuation, the SM8132A outputs a mode reset signal once every 1.4 seconds which automatically switches the output mode to ×1.0, and then a determination is
made whether to make the ×1.0 → ×1.5 mode switch.
1.4sec/cycle
(1)
Mode reset
(2)
VOUT mode
1.5 mode
Mode hold
L: hold
1.0 mode
min 80µs
max 200µs
(3)
ILED detector
ignore
VOUT
output voltage
4.2V (4)
Low ILED
detector
(5)
Switching from ×1.5 to ×1.0 mode due to the mode reset signal
(1) Mode reset signal is output once every 1.4 seconds.
(2) Switching from ×1.5 to ×1.0 mode due to the mode reset signal pulse.
(3) The mode hold time of 200µs (max) starts when output switches to ×1.0 mode. During this interval, the
mode is not switched even if an ILED undercurrent condition is detected.
(4) If VIN is low, the VOUT voltage momentarily drops because the boost function stops as a result of switching
to ×1.0 mode.
(5) The ILED undercurrent signal is ignored during the mode hold time, and the mode only switches in
response to the detector output after the mode hold time expires.
NIPPON PRECISION CIRCUITS INC.—13
SM8132A
For example, if the VIN voltage is low and the VOUT output voltage in ×1.0 mode does not provide sufficient
drive current, then the mode reset will cause a LED undercurrent condition. The LED undercurrent detector
circuit will output an LED undercurrent signal immediately after the switch to ×1.0 mode, but the output will
stay in ×1.0 mode and not return to ×1.5 mode for the duration of the mode hold time. Consequently, the VOUT
output is not boosted during the 85µs (min) to 200µs (max) mode hold time and the voltage drops and the LED
brightness is reduced. However, the LEDs are OFF for a maximum of 200µs only, and this is not discernible to
the naked eye and thus is not a problem.
1.0
1.5 threshold
VIN input voltage
Mode reset
(1.4sec/cycle)
Mode hold
(H: hold)
1.4sec
max
200µS
VOUT mode
(H: 1.5, L: 1.0)
4.2V
VOUT
output voltage
Low ILED detector
(H: low ILED)
VOUT drop due to the mode reset single
NIPPON PRECISION CIRCUITS INC.—14
SM8132A
PERIPHERAL PARTS
About the External Capacitors
The best capacitors for use with the SM8132A are multi-layer ceramic capacitors. When selecting a multi-layer
ceramic capacitor, only X5R and X7R dielectric types are strongly recommended, since the loss of capacitance
in various conditions is less than other types such as Z5U and Y5V. The much loss of capacitance in various
conditions may cause the output voltage unstable.
Table. The EIA three digit "TC" code
Lower temperature limit
High temperature limit
Maximum allowable capacitance
change from +25°C (0V DC)
X = −55°C
5 = +85°C
F = ± 7.5%
Y = −30°C
6 = +105°C
P = ± 10%
Z = +10°C
7 = +125°C
R = ± 15%
8 = +150°C
S = ± 22%
T = +22%/−33%
U = +22%/−56%
V = +22%/−82%
For example
: X5R
About the Input Capacitor "C4"
The parts layout of PCB may merely cause the “VOUT” output voltage unstable. In this case, increasing the
“C4” input capacitance value or adding another capacitor on the VIN input line is effective to solve the unstable output voltage.
About the LED Current Setting Resistor "RSET"
The LED drive current variation depends on the LED drive current setting resistor “RSET” variation. Therefore, a precise resistor is recommended for RSET. The ISET output current value is about 20µA, so a 1/10 watt
class resistor is acceptable as the RSET.
NIPPON PRECISION CIRCUITS INC.—15
SM8132A
TYPICAL APPLICATION CIRCUITS
C1 = 1µF
C1M C1P
2.8 to 4.3V
VIN
C2 = 1µF
C2M C2P
VOUT
Charge pump
1 /1.5
C4 = 4.7µF
C3 = 4.7µF
20mA 4
DIN1
Mode control
&
Output voltage control
&
Protection
DIN2
Current
control
&
Current
detect
TSD
DIN3
DIN4
EN
Control
logic
ISET
RSET = 20kΩ
GND
PGND
ILED MAX = 20mA circuit example
Note. If the driving LED is less than 4 pcs, unused DIN pins should be connect to GND.
NIPPON PRECISION CIRCUITS INC.—16
SM8132A
FOOTPRINT PATTERN
3.6 ± 0.1
2.2 ± 0.1
0.
32
0.25 ± 0.05
0.7 ± 0.1
2.2 ± 0.1
0.5 × 3 = 1.5 ± 0.05
3.6 ± 0.1
0.5 × 3 = 1.5 ± 0.05
NIPPON PRECISION CIRCUITS INC.—17
SM8132A
Please pay your attention to the following points at time of using the products shown in this document.
The products shown in this document (hereinafter “Products”) are not intended to be used for the apparatus that exerts harmful influence on
human lives due to the defects, failure or malfunction of the Products. Customers are requested to obtain prior written agreement for such
use from NIPPON PRECISION CIRCUITS INC. (hereinafter “NPC”). Customers shall be solely responsible for, and indemnify and hold NPC
free and harmless from, any and all claims, damages, losses, expenses or lawsuits, due to such use without such agreement. NPC reserves
the right to change the specifications of the Products in order to improve the characteristic or reliability thereof. NPC makes no claim or
warranty that the contents described in this document dose not infringe any intellectual property right or other similar right owned by third
parties. Therefore, NPC shall not be responsible for such problems, even if the use is in accordance with the descriptions provided in this
document. Any descriptions including applications, circuits, and the parameters of the Products in this document are for reference to use the
Products, and shall not be guaranteed free from defect, inapplicability to the design for the mass-production products without further testing
or modification. Customers are requested not to export or re-export, directly or indirectly, the Products to any country or any entity not in
compliance with or in violation of the national export administration laws, treaties, orders and regulations. Customers are requested
appropriately take steps to obtain required permissions or approvals from appropriate government agencies.
NIPPON PRECISION CIRCUITS INC.
15-6, Nihombashi-kabutocho, Chuo-ku,
Tokyo 103-0026, Japan
Telephone: +81-3-6667-6601
Facsimile: +81-3-6667-6611
http://www.npc.co.jp/
Email: [email protected]
NC0411AE
2005.05
NIPPON PRECISION CIRCUITS INC.—18