ROHM BD9898FV

1/4
STRUCTURE
Silicon Monolithic Integrated Circuit
NAME OF PRODUCT
DC-AC Inverter Control IC
TYPE
ＢＤ９８９８Ｆ、ＢＤ９８９８ＦＶ
FUNCTION
・
・
・
・
・
・
・
・
・
・
36V High voltage process
1ch control with Full-Bridge
Lamp current and voltage sense feed back control
Sequencing easily achieved with Soft Start Control
Short circuit protection with Timer Latch
Under Voltage Lock Out
Mode-selectable the operating or stand-by mode by stand-by pin
For slave IC, Synchronous operating with BD9215F/FV
BURST mode controlled by PWM and DC input
Output liner Control by external DC voltage
○Absolute Maximum Ratings（Ta = 25℃）
Parameter
Supply Voltage
BST pin
SW pin
BST-SW voltage difference
Operating Temperature Range
Storage Temperature Range
Maximum Junction Temperature
Power Dissipation
Symbol
VCC
BST
SW
BST-SW
Topr
Tstg
Tjmax
Pd
Limits
36
40
36
15
-40～+85
-55～+150
+150
749*1(BD9898F)
1062*2(BD9898FV)
Unit
V
V
V
V
℃
℃
℃
mW
*1
Pd derate at 6.0mW/℃ for temperature above Ta = 25℃ (When mounted on a PCB 70.0mm×70.0mm×1.6mm)
*2
Pd derate at 8.5mW/℃ for temperature above Ta = 25℃ (When mounted on a PCB 70.0mm×70.0mm×1.6mm)
〇Operating condition
Parameter
Supply voltage
BST voltage
BST-SW voltage difference
DRIVER frequency
BCT oscillation frequency
Symbol
Limits
Unit
VCC
BST
BST-SW
FOUT
fBCT
16.0～30.0 ※
5.0～37.5
5.0～14.0
30～110
0.05～1.00
V
V
V
kHz
kHz
※For Operation condition of Supply voltage, Please see NOTE FOR USE(4page), more information.
Status of this document
The Japanese version of this document is the official specification.
Please use the translation version of this document as a reference to expedite understanding of the official version.
If these are any uncertainty in translation version of this document, official version takes priority.
REV. B
2/4
○Electric Characteristics（Ta=25℃、VCC=24V、STB=UVLO=3.0V）
Parameter
（（WHOLE DEVICE））
Operating current
Stand-by current
（（STAND BY CONTROL））
Stand-by voltage H
Stand-by voltage L
（（UVLO BLOCK）））
Operating voltage (UVLO)
Hesteresis width (UVLO)
（（REG BLOCK））
REG output voltage
REG source current
（（OSC BLOCK））
RT pin Voltage
Soft start current
SS operation start Voltage
SS term END Voltage
SRT ON resistance
（（BOSC BLOCK））
BOSC Max voltage
BOSC Min voltage
BOSC constant current
BOSC frequency
（（FEED BACK BLOCK））
IS threshold voltage 1
IS threshold voltage 2
VS threshold voltage
IS source current 1
IS source current 2
VS source current
IS COMP detect voltage 1
IS COMP detect voltage 2
VREF input voltage range
（（OUTPUT BLOCK））
LN output sink resistance
LN output source resistance
HN output sink resistance
HN output source resistance
MAX DUTY
OFF period
Drive output frequency
（（TIMER LATCH BLOCK））
Timer Latch setting voltage
Timer Latch setting current
（（COMP BLOCK））
COMP over voltage detect voltage
Hysterisis width (COMP)
((Synchronous Block))
High voltage
Low voltage
CT_SYNC_OUT sink resistance
CT_SYNC_OUT source resistance
High voltage input range
Low voltage input range
Symbol
MIN.
Limits
TYP.
MAX.
Unit
Icc1
Icc2
－
－
5.5
60
10
140
mA
μA
VstH
VstL
2
-0.3
－
－
VCC
0.8
V
V
Vuvlo
⊿Vuvlo
2.16
0.085
2.25
0.110
2.34
0.135
V
V
VREG
IREG
7.35
20
7.50
－
7.65
－
V
mA
VRT
ISS
VSS_ST
VSS_ED
RSRT
1.05
1.7
0.18
1.35
－
1.50
2.2
0.20
1.50
85
1.95
2.7
0.22
1.65
170
V
μA
V
V
Ω
VBCTH
VBCTL
IBCT
fBCT
1.94
0.4
1.35/BRT
291
2
0.5
1.5/BRT
300
2.06
0.6
1.65/BRT
309
V
V
A
Hz
VIS1
VIS2
VVS
IIS1
IIS2
IVS
VISCOMP1
VISCOMP2
VREFIN
1.225
－
1.22
－
40
－
0.606
－
0.6
1.25
VREFIN
1.25
－
50
－
0.625
0.50
－
1.275
VIS1
1.28
0.9
60
0.9
0.644
－
1.6
V
V
V
μA
μA
μA
V
V
V
RsinkLN
RsourceLN
RsinkHN
RsourceLN
MAX DUTY
TOFF
FOUT
1.8
4.5
1.8
4.5
46.0
100
57.9
3.5
9.0
3.5
9.0
48.5
200
60
7.0
18.0
7.0
18.0
49.5
400
62.1
Ω
Ω
Ω
Ω
%
ns
kHz
VCP
ICP
3.88
1.6
4.0
2.1
4.12
2.6
V
μA
VCOMPH
⊿VCOMPH
3.88
0.15
4.0
0.20
4.12
0.25
V
V
VCT_SYNCH
VCT_SYNCL
3.8
－
－
－
2.5
-0.3
4.0
－
150
300
－
－
4.2
0.5
300
400
V
V
Ω
Ω
V
V
RSYNC_OUT_sink
RSYNC_OUT_source
VCT_SYNC_IN_H
VCT_SYNC_IN_L
（This product is not designed to be radiation-resistant.）
REV. B
VCT_SYNCH
1
Conditions
FOUT=60kHz, FB=GND, BST=OPEN
System ＯＮ
System ＯＦＦ
fBCT=0.3kHz
fBCT=0.3kHz
VBCT=0.2V
(BRT=37.8kΩ BCT=0.047μF)
VREF applying voltage
DUTY=2.2V
DUTY=0V IS=1.0V
VREFIN≧1.25V
VREFIN= 1V
No effect at VREF＞1.25V
VBST-VSW=7.0V
VBST-VSW=7.0V
FOUT=60kHz
RT=21k Ω
VSS＞1.65V
3/4
〇Package Dimensions
Device Mark
BD9898FV
BD9898F
１
１
Lot No.
SSOP-B28 (Unit:mm)
SOP28 (Unit:mm)
〇Pin Description
PIN No.
PIN NAME
1
PGND
2
LN2
NMOS FET driver
3
HN2
NMOS FET driver
4
SW2
Lower rail voltage for HN2 output
5
BST2
Boot-Strap input for HN2 output
6
CT_SYNC_IN
CT synchronous signal input pin
7
CT_SYNC_OUT
8
SRT
〇Block Diagram
REV. B
FUNCTION
Ground for FET drivers
CT synchronous signal output pin
External
adjusting
External
adjusting
resistor from SRT to RT for
the start-up triangle oscillator
resistor from RT to GND for
the triangle oscillator
9
RT
10
GND
11
BCT
12
BRT
13
DUTY
14
STB
15
CP
16
VREF
17
VS
Error amplifier input
18
IS
Error amplifier input
19
FB
Error amplifier output
20
SS
External capacitor from SS to GND for
Soft Start Control
21
COMP
22
VCC
23
UVLO
24
REG
Internal regulator output
25
BST1
Boot-Strap input for HN1 output
26
SW1
Lower rail voltage for HN1 output
27
HN1
NMOS FET driver
28
LN1
NMOS FET driver
GROUND
External capacitor from BCT to GND for
adjusting the BURST triangle oscillator
External resistor from BRT to GND for
adjusting the BURST triangle oscillator
Control PWM mode and BURST mode
Stand-by switch
External capacitor from CP to GND for
Timer Latch
Reference voltage input pin for Error
amplifier
Over voltage detect pin
Supply voltage input
External Under Voltage Lock Out
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〇NOTE FOR USE
１. This product is produced with strict quality control, but might be destroyed if used beyond its absolute
maximum ratings. Once IC is destroyed, failure mode will be difficult to determine, like short mode or
open mode. Therefore, physical protection countermeasure, like fuse is recommended in case operating
conditions go beyond the expected absolute maximum ratings.
２. The circuit functionality is guaranteed within of ambient temperature operation range as long as it is
within recommended operating range. The standard electrical characteristic values cannot be guaranteed
at other voltages in the operating ranges, however the variation will be small. When it is used in between
STB-UVLO Diode short etc., the IC can operate VCC≧9V. Please refer to a Technical Note in detail.
３. Mounting failures, such as misdirection or miscounts, may harm the device.
４. A strong electromagnetic field may cause the IC to malfunction.
５. The GND pin should be the location within ±0.3V compared with the PGND pin. ALL Pin (except BST1, BST2,
HN1, HN2,) Voltage should be under VCC voltage +0.3V
６. BD9898F, BD9898FV incorporate a built-in thermal shutdown circuit (TSD circuit). The thermal shutdown
circuit (TSD circuit) is designed only to shut the IC off to prevent runaway thermal operation. It is not
designed to protect the IC or guarantee its operation of the thermal shutdown circuit is assumed.
７. When modifying the external circuit components, make sure to leave an adequate margin for external
components actual value and tolerance as well as dispersion of the IC.
８. About the external FET, the parasitic Capacitor may cause the gate voltage to change, when the drain voltage
is switching. Make sure to leave adequate margin for this IC variation.
９. Under operating CP charge (under error mode) analog dimming and burst dimming are not operate.
10. Under operating Slow Start Control (SS is less than 1.5V), It does not operate Timer Latch.
11. By STB voltage, BD9898F, BD9898FV are changed to 2 states. Therefore, do not input STB pin voltage between
one state and the other state (0.8～2.0V).
12. The pin connected a connector need to connect to the resistor for electrical surge destruction.
13. This IC is a monolithic IC which (as shown is Fig-1) has P+ substrate and between the various pins.
A P-N junction is formed from this P layer of each pin. For example, the relation between each potential
is as follows,
○(When GND > PinB and GND > PinA, the P-N junction operates as a parasitic diode.)
○(When PinB > GND > PinA, the P-N junction operates as a parasitic transistor.)
Parasitic diodes can occur inevitably in the structure of the IC. The operation of parasitic diodes can
result in mutual interference among circuits as well as operation faults and physical damage. Accordingly
you must not use methods by which parasitic diodes operate, such as applying a voltage that is lower than
the GND (P substrate) voltage to an input pin.
Transistor (NPN)
Resistance
(PinA)
(PinB)
B
E
C
Ｃ
GND
P
P＋
N
P＋
N
Ｎ
N
Ｎ
P substrate
GND
Parasitic diode
N
P substrate
GND
Parasitic diode
(PinB)
(PinA)
B
CＣ
Ｂ
EＥ
Parasitic diode
GND
GND
Other adjacent components
Parasitic diode
Fig-1 Simplified structure of a Bipolar IC
REV. B
Notice
Notes
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Examples of application circuits, circuit constants and any other information contained herein
illustrate the standard usage and operations of the Products. The peripheral conditions must
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