IRF IRS20955SPBF

PRELIMINARY
Data Sheet No. PD60303
IRS20955(S)PbF
PROTECTED DIGITAL AUDIO DRIVER
Features
·
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·
·
·
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Product Summary
Floating PWM input enables easy half-bridge
implementation
Programmable bidirectional over-current protection
with self-reset function
Programmable preset deadtime for improved THD
performances
High noise immunity
±100 V ratings deliver up to 500 W in output power
3.3 V/5 V logic compatible input
Operates up to 800 kHz
RoHS compliant
± 100 V
1.0 A
1.2 A
15 ns, 25 ns,
35 ns, 45ns
90 ns
500 ns (max)
VOFFSET (max)
Gate driver
Io+
Io-
Selectable deadtime
Propagation delay
OC protection delay
Shutdown propagation
delay
250 ns (max)
Description
The IRS20955 is a high voltage, high speed MOSFET driver
with a floating PWM input designed for Class D audio
amplifier applications.
Package
Bi-directional current sensing detects over-current
conditions during positive and negative load currents without
any external shunt resistors. A built-in protection control
block provides a secure protection sequence against overcurrent conditions and a programmable reset timer.
The internal deadtime generation block enables accurate
gate switching and optimum deadtime setting for better
audio performance, such as lower THD and lower audio
noise floor.
16-Lead PDIP
16-Lead SOIC
Typical Connection
IRS20955 (S)
PWM
VDD
CSH
CSD
VB
IN
HO
VSS
VS
NC
NC
VREF
(Please refer to Lead
Assignments for correct
pin configuration. This
diagram shows
electrical connections
only)
OCSET
DT
+B
Speaker
VCC
LO
COM
Vcc
12V
-B
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1
IRS20955(S)PbF
PRELIMINARY
Absolute Maximum Ratings
Absolute maximum ratings indicate sustained limits beyond which damage to the device may occur. All voltage parameters
are absolute voltages referenced to VSS; all currents are defined positive into any lead. The thermal resistance and power
dissipation ratings are measured under board mounted and still air conditions.
Symbol
Definition
VB
High-side floating supply voltage
VS
High-side floating supply voltage (Note1)
Min.
Max.
-0.3
220
VB+0.3
VB-20
VHO
High-side floating output voltage
Vs-0.3
VB+0.3
VCSH
CSH pin input voltage
Vs-0.3
VB+0.3
VCC
Low-side fixed supply voltage (Note1)
-0.3
20
VLO
Low-side output voltage
-0.3
VCC +0.3
VDD
Floating input supply voltage
-0.3
VSS
Floating input supply voltage (Note1)
(See IDDZ)
210
VDD+0.3
VIN
PWM input voltage
VSS -0.3
VDD+0.3
VCSD
CSD pin input voltage
VDD+0.3
VDT
DT pin input voltage
VSS -0.3
-0.3
V
VCC +0.3
OCSET pin input voltage
-0.3
VCC +0.3
VREF
VREF pin voltage
-0.3
VCC +0.3
IDDZ
Floating input supply Zener clamp current (Note1)
-
10
ICCZ
Low side supply Zener clamp current (Note1)
-
10
IBSZ
Floating supply Zener clamp current (Note1)
-
10
IOREF
Reference output current
-
VOCSET
Units
mA
d VS /dt
Allowable VS voltage slew rate
-
5
50
d VSS /dt
Allowable VSS voltage slew rate (Note2)
-
50
d VSS /dt
Allowable VSS voltage slew rate upon power-up (Note3)
-
50
Maximum power dissipation
-
1.0
W
Thermal resistance, junction to ambient
-
115
°C/W
PD
Rth,JA
TJ
Junction temperature
-
150
TS
Storage temperature
-55
150
TL
Lead temperature (soldering, 10 seconds)
-
300
V/ns
°C
Note1: VDD - VSS, VCC -COM and VB - VS contain internal shunt Zener diodes. Please note that the voltage ratings of these
can be limited by the clamping current.
Note2: For the rising and falling edges of step signal of 10 V. Vss=15 V to 200 V.
Note3: Vss ramps up from 0 V to 200 V.
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2
IRS20955(S)PbF
PRELIMINARY
Recommended Operating Conditions
For proper operation, the device should be used within the recommended conditions below. The Vs and COM offset ratings
are tested with supplies biased at IDD=5 mA, VCC=12 V and VB-VS=12 V.
Symbol
VB
VS
Definition
High-side floating supply absolute voltage
High-side floating supply offset voltage
Min.
Max.
Units
Vs+10
Note 1
Vs+18
100
V
mA
IDDZ
Floating input supply zener clamp current
1
5
VSS
Floating input supply absolute voltage
0
200
VHO
High-side floating output voltage
Vs
VB
VCC
Low-side fixed supply voltage
10
18
VLO
Low-side output voltage
0
VCC
VSS
VDD
0
VCC
VIN
PWM input voltage
VCSD
CSD pin input voltage
VDT
DT pin input voltage
IOREF
VOCSET
TA
V
Reference output current to COM (Note 2)
0.3
0.8
mA
OCSET pin input voltage
0.5
5
V
Ambient temperature
-40
125
°C
Note 1: Logic operational for VS equal to –5 V to +200 V. Logic state held for VS equal to –5 V to –VBS.
Note 2: Nominal voltage for VREF is 5 V. IOREF of 0.3 mA – 0.8 mA dictates total external resistor value on VREF to be 6.3 kΩ
to 16.7 kΩ.
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3
IRS20955(S)PbF
PRELIMINARY
Electrical Characteristics
VCC ,VBS= 12 V, IDD=5 mA, VSS=20 V, VS=0 V,CL=1 nF and TA=25 °C unless otherwise specified.
Symbol Definition
Low-Side Supply
UVCC+
UVCCIQCC
VCLAMPL
VCC supply UVLO positive threshold
VCC supply UVLO negative threshold
Low-side quiescent current
Low-side Zener diode clamp voltage
Min
Typ
Max
Units
Test Conditions
8.4
8.2
19.6
8.9
8.7
20.4
9.4
9.2
3
21.6
8.0
8.5
9.0
7.8
8.3
8.8
19.6
20.4
1
50
21.6
8.2
8.7
9.2
7.7
8.2
8.7
-
-
1
mA
VDD=9.5 V +VSS
9.8
10.2
10.8
V
IDD=5 mA
-
-
50
µA
VDD=VSS =200 V
2.3
-
1.9
1.9
-
1.5
40
1
V
mA
V
VDT = VCC
ICC=5 mA
High-Side Floating Supply
UVBS+
UVBSIQBS
ILKH
VCLAMPH
High-side well UVLO positive
threshold
High-side well UVLO negative
threshold
High-side quiescent current
High-side to low-side leakage current
High-side Zener diode clamp voltage
V
mA
µA
V
VB=VS =200 V
IBS=5 mA
Floating Input Supply
UVDD+
UVDDIQDD
VCLAMPM
ILKM
VDD, VSS floating supply UVLO
positive threshold
VDD, VSS floating supply UVLO
negative threshold
Floating input quiescent current
Floating input Zener diode clamp
voltage
Floating input side to low-side leakage
current
VSS =0 V
V
VSS =0 V
Floating PWM Input
VIH
VIL
IIN+
IIN-
Logic high input threshold voltage
Logic low input threshold voltage
Logic “1” input bias current
Logic “0” input bias current
V
µA
VIN =3.3 V
VIN = VSS
Protection
VREF
Reference output voltage
4.8
5.1
5.4
Vth,OCL
Low-side OC threshold in Vs
1.1
1.2
1.3
Vth,OCH
High-side OC threshold in VCSH
1.1+ VS
1.2+ VS
1.3+ VS
Vth,1
Vth,2
ICSD+
ICSDtSD
tOCH
tOCL
CSD pin shutdown release threshold
CSD pin self reset threshold
CSD pin discharge current
CSD pin charge current
Shutdown propagation delay from
VCSD > VSS + Vth,OCH to shutdown
Propagation delay time from VCSH >
Vth,OCH to shutdown
Propagation delay time from Vs>
Vth,OCL to shutdown
0.62 x VDD
0.26 x VDD
70
70
0.70 x VDD
0.30 x VDD
100
100
0.78 x VDD
0.34 x VDD
130
130
-
-
250
-
-
500
-
-
500
-
1.0
-
-
1.2
-
-
-
0.1
V
IOREF =0.5 mA
OCSET=1.2 V,
Fig. 3
VS=200 V,
Fig. 4
VSS =0 V
µA
VSD = VSS +5 V
Fig. 2
ns
Fig. 4
Fig. 3
Gate Driver
Io+
IoVOL
Output high short circuit current
(source)
Output low short circuit current (sink)
Low level output voltage
LO – COM, HO – VS
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A
VO =0 V, PW<10 µs
VO =12 V, PW<10 µs
V
4
IRS20955(S)PbF
PRELIMINARY
Electrical Characteristics (cont.)
VCC ,VBS= 12 V, IDD=5 mA, VSS=20 V, VS=0 V,CL=1 nF and TA=25 °C unless otherwise specified.
VOH
tr
tf
ton,1
toff,1
ton,2
toff,2
DT1
DT2
DT3
DT4
VDT1
VDT2
VDT3
High level output voltage
VCC – LO, VB – HO
Turn-on rise time
Turn-off fall time
High-side and low-side turn-on
propagation delay, floating inputs
High-side and low-side turn-off
propagation delay, floating inputs
High-side and low-side turn-on
propagation delay, non-floating inputs
High-side and low-side turn-off
propagation delay, non-floating inputs
Deadtime: LO turn-off to HO turn-on
(DTLO-HO) & HO turn-off to LO turn-on
(DTHO-LO)
Deadtime: LO turn-off to HO turn-on
(DTLO-HO) & HO turn-off to LO turn-on
(DTHO-LO)
Deadtime: LO turn-off to HO turn-on
(DTLO-HO) & HO turn-off to LO turn-on
(DTHO-LO)
Deadtime: LO turn-off to HO turn-on
(DTLO-HO) & HO turn-off to LO turn-on
(DTHO-LO)VDT= VDT4
DT mode select threshold 2
DT mode select threshold 3
DT mode select threshold 4
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-
-
1.4
-
15
10
-
-
105
-
-
90
-
-
105
-
-
90
-
8
15
22
15
25
35
VDT1>VDT> VDT2,
VSS = COM
20
35
50
VDT2>VDT> VDT3,
VSS = COM
25
45
60
VDT3>VDT> VDT4,
VSS = COM
0.51(V cc)
0.32(V cc)
0.21(V cc)
0.57(V cc)
0.36(V cc)
0.23(V cc)
0.63(V cc)
0.40(V cc)
0.25(V cc)
V
IO=0 A
VDT = VCC,
VS = 100 V,
VSS = 100 V
VDT = VCC,
VS = 100V,
VSS = COM
ns
VDT>VDT1,
VSS = COM
V
5
IRS20955(S)PbF
PRELIMINARY
Lead Definitions
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Symbol
VDD
CSD
IN
VSS
NC
VREF
OCSET
DT
COM
LO
VCC
NC
VS
HO
VB
CSH
Description
Floating input positive supply
Shutdown timing capacitor, referenced to VSS
PWM non-inverting input, in phase with HO
Floating input supply return
5 V reference output for setting OCSET
Low-side over current threshold setting, referenced to COM
Input for programmable deadtime, referenced to COM
Low-side supply return
Low-side output
Low-side logic supply
High-side floating supply return
High-side output
High-side floating supply
High-side over current sensing input, referenced to VS
VDD
1
16
CSH
CSD
2
15
VB
IN
3
14
HO
VSS
4
13
VS
NC
5
12
NC
VREF
6
11
VCC
OCSET
7
10
LO
8
9
COM
DT
IRS20955(S)
Pin #
IRS20955(S)
16-Lead SOIC (narrow body)
16-Lead PDIP
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6
IRS20955(S)PbF
PRELIMINARY
Block Diagram
FLOATING INPUT
VDD
VB
UV
HIGH
SIDE
CS
INPUT
LOGIC
Q
HO
20.8V
IN
CSH
UV
DETECT
UV
DETECT
10.4V
HV
LEVEL
SHIFT
VSS
HV
LEVEL
SHIFT
FLOATING HIGH SIDE
VS
HV
LEVEL
SHIFT
5V REG
VCC
UV
DETECT
CHARGE/
DISCHARGE
CSD
SD
PROTECTION
CONTROL
HV
LEVEL
SHIFT
HV
LEVEL
SHIFT
DT
20.8V
DEAD-TIME
LO
COM
LOW SIDE CS
5.1V REFERENCE
OCSET
VREF
DT
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7
IRS20955(S)PbF
PRELIMINARY
50%
IN
50%
t o n (L )
t o ff(L )
t o ff(H )
t o n (H )
90%
VS
VthOCL
LO
10%
D T H O -L O
D T L O -H O
90%
90%
HO
LO
10%
tOCL
Figure 1. Switching Time Waveform
Definitions
Figure 3. VS > VTH,OCL to Shutdown Waveform
Vth1
CSD
VthOCH
CSH
VS
90%
90%
HO/LO
HO
tSD
Figure 2. CSD to Shutdown Waveform
Definitions
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tOCH
Figure 4. VS > VTH,OCL to Shutdown Waveform
8
IRS20955(S)PbF
PRELIMINARY
Functional Description
Over-Current Protection (OCP)
Floating PWM Input
The IRS20955S accepts floating inputs, enabling
easy half-bridge implementation. VDD, CSD and IN
refer to VSS. As a result, the PWM input signal can
directly feed into IN while referencing VSS, which is
typically the midpoint between the positive and
negative DC bus voltages in a half-bridge
configuration.
The IRS20955S also accepts a non-floating input
when VSS is tied to COM.
VDD
HV
LEVEL
SHIFT
CSD
10.4V
IN
PROTECTION
VSS
The IRS20955S features over-current protection to
protect the power MOSFETs during abnormal load
conditions. The IRS20955S engages a sequence of
events when it detects the over-current condition
during high-side or low-side turn on.
As soon as either the high-side or low-side current
sensing block detects over-current:
1. The OC Latch (OCL) flips logic states and
shutdowns the outputs LO and HO.
2. The CSD pin starts discharging the external
capacitor Ct.
3. When VCSD, the voltage across Ct, falls
below the lower threshold Vth2, an output
signal from COMP2 resets OCL.
4. The CSD pin starts charging the external
capacitor Ct.
5. When VCSD goes above the upper threshold
Vth1, the logic on COMP1 flips and the IC
resumes operation.
Floating Input Isolation
Floating Bias
0V – 200V
As long as the over current condition exists, the IC
will repeat the over current protection sequence.
COM
IRS20955
Figure 5. Floating PWM Input Structure
Figure 6. Over-Current Protection Timing Chart
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9
IRS20955(S)PbF
PRELIMINARY
VDD
Vth1
`
COMP1
CSD
OC
S
Q
UVLO(VB)
`
COMP2
Ct
R
OC DET (H)
Vth2
VSS
HV
LEVEL
SHIFT
HV
LEVEL
SHIFT
FLOATING INPUT
HV
LEVEL
SHIFT
FLOATING HIGH SIDE
LOW SIDE
OC DET (L)
UVLO(VCC)
SD
PWM
HO
DEAD TIME
`
LO
Figure 7. Shutdown Functional Block Diagram
Designing Ct
Protection Control
The internal protection control block dictates the
operational mode-norma, or shutdown, using the
input of the CSD pin. The IC functions as expected
in the normal mode. In shutdown mode, the IC
forces LO and HO to output 0 V with respect to
COM and VS to turn off the power MOSFETs.
The CSD pin provides five functions.
1. Power up delay timer
2. Self-reset timer
3. Shutdown input
4. Latched protection configuration
5. Shutdown status output (host I/F)
Self Reset Protection
By putting a capacitor between CSD and VSS, the
IRS20955S can reset itself after entering shutdown
mode.
VDD
Ct
VB
IN
HO
VSS
VS
NC
NC
OCSET
DT
t RESET ⋅ I CSD
1.1 ⋅VDD
[F]
Ct =
t SU ⋅ I CSD
0.7 ⋅ VDD
[F]
VCC
LO
COM
Figure 8. Self Reset Protection Configuration
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Ct =
CSH
CSD
VREF
The timing capacitor, Ct, is used to program tRESET
and tSU.
• tRESET, is the amount of time that elapses
from when the IC enters shutdown mode to
the time when the IC resumes operation.
tRESET should be long enough to avoid over
heating the MOSFET from the repetitive
sequence of shutting down and resuming
operation during over current conditions. In
most of applications, the minimum
recommended time for tRESET is 0.1.
• tSU is the amount of time between powering
up the IC in shutdown mode to the moment
the IC releases shutdown to begin normal
operation.
The values chosen for tRESET and tSU will determine
the capacitance of Ct using the given equations:
where ICSD = the charge/discharge current at the
CSD pin
VDD = the supply voltage with respect to VSS.
10
IRS20955(S)PbF
PRELIMINARY
Shutdown Input
Interfacing with System Controller
When VCSD falls below Vth2, the IRS20955S begins
to charge Ct in an attempt to resume operation.
Once the voltage of the CSD pin rises above the
upper threshold, Vth1, the IC begins to operate
normally again.
The IRS20955S can communicate with an external
system controller through a simple interfacing circuit
such as the one shown in Figure 11. A generic PNP
transistor, shown as U1, can detect the sink current
at the CSD pin during an OCP event and output a
shutdown signal to an external system controller.
Another generic NPN transistor, shown as U2, can
then reset the internal protection logic by pulling the
CSD voltage below Vth2 for a minimum of 200 ns.
Note that the CSD pin is configured to operate in
latched OCP. After the power up sequence, a reset
signal to the CSD pin is required to release the IC
from shutdown mode.
VDD
SHUTDOWN
CSH
CSD
VB
IN
HO
VSS
VS
NC
NC
VREF
OCSET
DT
VCC
LO
COM
Figure 9. Shutdown Input
Latched Protection
Connecting CSD to VDD through a 10 kΩ or less
resistor configures the over current protection latch.
The latch locks the IC in shutdown mode after over
current is detected. An external reset switch can be
used to bring CSD below the lower threshold Vth2 for
a minimum of 200 ns to properly reset the latch.
After the power up sequence, a reset signal to the
CSD pin is required to release the IC from shutdown
mode.
VDD
<10k
RESET
CSH
CSD
VB
IN
HO
VSS
VS
NC
NC
VREF
OCSET
DT
VCC
LO
COM
Figure 10. Latched Protection Configuration
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Figure 11. Interfacing with System Controller
Programming OCP Trip Level
In a Class D audio amplifier, the direction of the load
current alternates with the audio input signal. An
over-current condition can therefore occur during
either a positive current cycle or a negative current
cycle. The IRS20955 uses the RDS(ON) of the output
MOSFETs as current sensing resistors. Due to the
structural constraints of high voltage ICs, current
sensing is implemented differently for high side and
low side. If the measured current exceeds a
predetermined threshold, the OCP block outputs a
signal to the protection block to shutdown the
MOSFET to protect the switching devices.
11
IRS20955(S)PbF
PRELIMINARY
D1
R2
+B
CSH
UV
DETECT
R1
VB
UV
HIGH
SIDE
CS
Q
Dbs
R3
HO
Q1
Cbs
OUT
HV
LEVEL
SHIFT
FLOATING HIGH SIDE
5V REG
VS
HV
LEVEL
SHIFT
Vcc
VCC
UV
DETECT
DEAD TIME
Q2
LO
SD
-B
COM
R5
LOW SIDE CS
OCSET
R4
VREF
Figure 12. Bi-directional Over Current Protection
Low-side Over Current Sensing
For negative load currents, low-side over current
sensing monitors the load condition and shuts down
switching operation if the load current exceeds the
preset trip level.
Low-side current sensing is based on the
measurement of VDS across the low side MOFET
during low-side turn on. In order to avoid triggering
OCP from overshoot, a blanking interval inserted
after LO turn on disables over current detection for
450 ns.
The OCSET pin is used to program the threshold for
low-side over current sensing. When the VDS
measured across the low-side MOSFET exceeds
the voltage at the OCSET pin with respect COM, the
IRS20955S begins the OCP sequence described
earlier.
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Since the voltage from VS to COM is compared to
the voltage at the OCSET pin, the voltage at OCSET
determines the trip level for over-current detection.
By selecting the trip level for over-current, the
voltage at OCSET can be calculated using the
equation below.
VOCSET = VDS(LOW SIDE) = ITRIP+ x RDS(ON)
In order to minimize the effect of the input bias
current at the OCSET pin, select resistor values for
R4 and R5 such that the current through the voltage
divider is 0.5 mA or more.
* Note: Using VREF to generate an input to OCSET
through a resistive divider provides improved
immunity from fluctuations in VCC.
12
IRS20955(S)PbF
PRELIMINARY
+B
Q1
OC
REF
OCREF
5.1V
R4
R5
OUT
VS
0.5mA
-
OCSET
OC
+
OC Comparator
COM
LO
LO
Q2
IRS20955
-B
Figure 13. Low-side Over-Current Sensing
Low-Side Over-Current Setting
Let the low-side MOSFET have an RDS(ON) of 100
mΩ and set the current trip level to 30 A. VOCSET is
given by:
VOCSET = ITRIP+ x RDS(ON) = 30 A x 100 mΩ = 3.0 V
Choose R4+R5=10 kΩ to properly load the VREF
pin.
R5 =
=
VOCSET
⋅ 10 kΩ
VREF
3.0 V
⋅ 10 kΩ
5.1 V
= 5.8 kΩ
where VREF = 5.1 V
Based on the E-12 series of resistor values, choose
R5 to be 5.6 kΩ and R4 to be 3.9 kΩ to complete
the design.
In general, RDS(ON) has a positive temperature
coefficient that needs to be considered when setting
the threshold level. Variations in RDS(ON) will affect
the selection of external or internal component
values.
High-side current sensing is based on the
measurement of VDS across the high-side MOFET
during high-side turn on through pins CSH and VS.
In order to avoid triggering OCP from overshoot, a
blanking interval inserted after HO turn on disables
over current detection for 450 ns.
In contrast to low-side current sensing, the threshold
at which the CSH pin engages OC protection is
internally fixed at 1.2 V. An external resistive divider
R2 and R3 can be used to program a higher
threshold.
An external reverse blocking diode, D1, is required
to block high voltages from feeding into the CSH pin
while the high-side is off. Due to a forward voltage
drop of 0.6 V across D1, the minimum threshold
required for high-side over current protection is 0.6
V.
VCSH =
where VDS(HIGH SIDE) = the drain to source voltage of
the high-side MOSFET during high-side turn on
VF(D1) = the forward drop voltage of D1
Since VDS(HIGH SIDE) is determined by the product of
drain current ID and RDS(ON) of the high-side
MOSFET. VCSH can be rewritten as:
High-Side Over-Current Sensing
For positive load currents, high-side over current
sensing also monitors the load condition and shuts
down the switching operation if the load current
exceeds the preset trip level.
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R3
⋅ (V DS ( HIGHSIDE ) + V F ( D1) )
R 2 + R3
VCSH =
R3
⋅ (RDS ( ON ) ⋅ I D + VF ( D1) )
R 2 + R3
Note: The reverse blocking diode D1 is forward
biased by a 10 kΩ resistor R1 when the high-side
MOSFET is on.
13
IRS20955(S)PbF
PRELIMINARY
OC
D1
R2
CSH
CSH
Comparator
+B
R1
VB
+
-
R3
1.2V
HO
HO
Q1
OUT
VS
Vcc
LO
Q2
IRS20955
-B
Figure 14. Programming High-Side Over-Current Threshold
High-Side Over-Current Setting
Figure 14 demonstrates the typical circuitry used for
high-side current sensing. In the following example,
the over current protection level is set to trip at 30 A
using a MOSFET with an RDS(ON) of 100 mΩ. The
component values of R2 and R3 can be calculated
using the following formula:
Let R2 + R3=10 kΩ.
R3 = 10 kΩ ⋅
VthOCH
VDS + VF
where VthOCL = 1.2 V
VF = the forward voltage of reverse blocking
diode D1 = 0.6 V.
VDS@ID=30A = the voltage drop across the
high-side MOSFET when the MOSFET current is 30
A.
Therefore, VDS@ID=30A = ID x RDS(ON) = 30 A x 100 mΩ
=3V
Based on the formulas above, R2 = 6.8 kΩ and R3
= 3.3 kΩ.
Choosing the Right Reverse Blocking Diode
The selection of the appropriate reverse blocking
diode used in place of D1 depends on its voltage
rating and speed. To effectively block bus voltages,
the reverse voltage must be higher than the voltage
difference between +B and -B and the reverse
recovery time must be as fast as the boot strap
charging diode. A diode such as the Philips BAV21
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W, a 200 V, 50 ns high speed switching diode, is
more than sufficient.
Deadtime Generator
Deadtime is a blanking period inserted between
high-side turn on and low-side turn on to prevent
shoot through. In the IRS20955S, an internal deadtime generation block allows the user to select the
optimum deadtime from a range of preset values.
Selecting a preset deadtime through the DT/SD pin
voltage can easily be done through an external
voltage divider. This way of setting deadtime
prevents outside noise from modulating the
switching timing, which is critical to the audio
performances.
How to Determine Optimal Deadtime
The effective deadtime in an actual application
differs from the deadtime specified in this datasheet
due to the switching fall time, tf.. The deadtime value
in this datasheet is defined as the time period
between the beginning of turn-off on one side of the
switching stage and the beginning of turn-on on the
other side as shown in Figure 15. The fall time of
MOSFET gate voltage must be subtracted from the
deadtime value in the datasheet to determine the
effective deadtime of a Class D audio amplifier.
(Effective deadtime) = (Deadtime in datasheet) – tf.
14
IRS20955(S)PbF
PRELIMINARY
Programming Deadtime
90%
HO (or LO)
Effective dead - time
10%
tf
LO (or HO)
Dead-time
in
datasheet
10%
Figure 15. Effective Deadtime
A longer deadtime period is required for a MOSFET
with a larger gate charge value because of the
longer tf.. Although a shorter effective deadtime
setting is beneficial to achieving better linearity in
Class D amplifiers, the likelihood of shoot-through
current increases with narrower deadtime settings.
Negative values of effective deadtime may cause
excessive heat dissipation in the MOSFETs, leading
to
potentially
serious
damage.
The IRS20955S selects the deadtime from a range
of preset deadtime values based on the voltage
applied at the DT pin. An internal comparator
translates the DT input to a predetermined deadtime by comparing the input with internal reference
voltages. These internal reference voltages are set
in the IC through a resistive voltage divider using
VCC. The relationship between the operation mode
and the voltage at DT pin is illustrated in the
Figure16 below.
Dead- time
15nS
25nS
35nS
45nS
0.23 xVcc
To calculate the optimal deadtime in a given
application, the fall time tf for both HO and LO in the
actual circuit need to be taken into account. In
addition, variations in temperature and device
parameters could also affect the effective deadtime
in the actual circuit. Therefore, a minimum effective
deadtime of 10 ns is recommended to avoid shootthrough current over the range of operating
temperatures and supply voltages.
0.36 xVcc
0.57 xVcc
Vcc
VDT
Figure 16. Deadtime vs. VDT
Table 1 suggests pairs of resistor values used in the
voltage divider for selecting deadtime. Resistors
with up to 5% tolerance are acceptable when using
these values.
IRS20955
>0.5mA
Vcc
R1
DT
R2
COM
Figure 17. External Voltage Divider
Table 1 Recommended Resistor Values for Deadtime Selection
Deadtime Mode
R1
R2
DT/SD Voltage
DT1
Open
1.00(VCC)
<10 kΩ
DT2
0.71(VCC)
3.3 kΩ
8.2 kΩ
DT2
0.46(V
5.6 kΩ
4.7 kΩ
CC)
DT4
0.29(VCC)
8.2 kΩ
3.3 kΩ
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15
IRS20955(S)PbF
PRELIMINARY
RDD ≤
V+ B − 10.8 V
I DD
[Ω]
Example: In the case where the average PWM
switching frequency is 400 kHz, the required IDD is
1.18 mA. Based on this calculation, a 50 V power
supply voltage would require RDD to be 33 kΩ or
less.
Furthermore, make sure IDD is below the maximum
zener diode bias current, IDDZ, during static state
conditions.
I DDZ ≥
V+ B − 10.8 V
− 0.5 mA
Rdd
20.8V
The value of RDD used to supply IDD should meet the
following requirement:
IQBS
IDD ≈ 1.5 mA x 300 x 10-9 x switching frequency +
0.5 mA + 0.5 mA
(Dynamic
power
consumption)
(Static) (Zener bias)
20.8V
VDD is designed to be supplied with an internal
Zener diode clamp. IDD, the supply current for VDD,
can be estimated by:
The value of this charging resistor is subject to
several constraints:
- The minimum value of RCHARGE is limited by
the leakage current of the bootstrap voltage
supply through RCHARGE, which would limit
the maximum PWM modulation index of the
system.
- The maximum value of RCHARGE is limited by
the current charge capability of the resistor
during startup:
I CHARGE > I QBS
where ICHARGE = the current through
RCHARGE
IQBS = the high side quiescent
current.
IQBC
Supplying VDD
Figure 19. Boot Strap Supply Pre-charging
Start-up Sequence (UVLO)
Rdd
IRS20955S
VDD
CSH
VB
CSD
IN
PWM
+B
10.4V
HO
VSS
VS
NC
NC
VREF
OCSET
DT
VCC
LO
COM
Vcc
The protection control block in the IRS20955S
monitors the status of VDD and VCC to ensure that
both voltage supplies are above the UVLO (undervoltage lockout) threshold before beginning normal
operation. If either VDD or VCC is below the under
voltage threshold, LO and HO are disabled in
shutdown mode until both VDD and VCC rise above
the voltage threshold.
12V
Power-down Sequence
-B
Figure 18. Supplying VDD
As soon as VDD or VCC falls below the UVLO
threshold, protection logic in the IRS20955S turns
off LO and HO, shutting off the power MOSFETs.
Charging VBS Prior to Start
The high-side bootstrap capacitor can be charged
through a resistor from the positive supply bus to the
VB pin by utilizing an internal 20.8 V Zener diode
between VB and VS. This scheme eliminates the
need to charge the boot strap capacitor through lowside turn on during start-up.
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Figure 20. IRS20955 UVLO Timing Chart
16
IRS20955(S)PbF
PRELIMINARY
PMID = PZDD + PLDD
Power Supply Decoupling
As the IRS20955S contains analog circuitry, careful
attention must be given to decoupling the power
supplies for proper operation. Ceramic capacitors of
0.1 µF or more should be placed close to the power
supply pins of the IC on the board.
Please refer to the application note AN-978 for
general design considerations of a high voltage gate
driver IC.
VSS can go below COM when a negative supply is
missing in a dual supply configuration. In this case,
excessive negative VSS voltage with respect to COM
could damage the IRS20955S. Having a diode to
clamp potential negative biases to VSS is
recommended to protect the IC. A standard
recovery diode with a current rating of 1 A such as
the 1N4002 is sufficient for this purpose.
CSH
CSD
VB
IN
HO
VSS
VS
NC
NC
VREF
Negative VSS
Clamping Diode
OCSET
DT
where
PZDD = the power dissipation from the internal
Zener diode clamping VDD
PLDD = the power dissipation from the internal
logic circuitry
V+BUS = the positive bus voltage feeding VDD
RDD = the resistor feeding VDD from V+BUS
*For obtaining the value of RDD, refer to the
section “Supplying VDD.”
VSS Negative Bias Clamping
VDD
V
− VDD
≈ + BUS
⋅VDD
RDD
2. PLSM: Power Dissipation of the Input
Level Shifter
PLSM = 2 nC x fsw x VSS,BIAS
where
fSW = the PWM switching frequency
VSS,BIAS = the bias voltage of VSS with respect to
COM
VCC
3. PLOW: Power Dissipation in Low-Side
LO
COM
-Vbus
Figure 21. Negative VSS Clamping
Junction Temperature Estimation
The power dissipation in the IRS20955S is
dominated by the following items:
- PMID: Power dissipation of the floating input
logic and protection circuitry
- PLSM: Power dissipation of the input level
shifter
- PLOW: Power dissipation in low-side
- PLSH: Power dissipation of the high-side
level shifter
- PHIGH: Power dissipation in high-side
The power dissipation in low-side comes from
the losses of the logic circuitry and the losses of
driving LO.
PLOW = PLDD + PLO
⎛
⎞
RO
⎟
= (I QCC ⋅ VCC ) + ⎜Vcc ⋅ Qg ⋅ f SW ⋅
⎜
⎟
+
+
R
R
R
O
g
g
(int)
⎝
⎠
where
PLDD = the power dissipation from the internal logic
circuitry
PLO = the power dissipation from the gate drive
stage to LO
RO = the output impedance of LO, typically 10 Ω for
the IRS20955S
1. PMID: Power Dissipation of the Floating
Input Logic and Protection Circuitry
Rg(int) = the internal gate resistance of the low side
MOSFET driver, typically 10 Ω for the IRS20955S
The power dissipation of the floating input
section is given by:
Rg = the external gate resistance of the low side
MOSFET
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Qg = total gate charge of the low side MOSFET
17
IRS20955(S)PbF
PRELIMINARY
4. PLSH: Power Dissipation of the High-Side
Level Shifter
PLSH = 0.4 nC x fsw x VBUS
where
fSW = the PWM switching frequency
VBUS = the difference between the positive bus
voltage and negative bus voltage
Total power dissipation, Pd, is given by
Pd = PMID + PLSM + PLOW + PHSM + PHIGH .
Given Rth,JA, the thermal resistance between the
ambient and junction temperature, TJ, the junction
temperature, can be calculated from the formula
provided below.
TJ = Rth , JA ⋅ Pd + TA < 150 °C
5. PHIGH: Power Dissipation in High-side
The power dissipation in high-side comes from
the losses of the logic circuitry and the losses of
driving LO.
PHIGH = PLDD + PHO
⎛
⎞
RO
⎟
= (I QBS ⋅ VBS ) + ⎜VBS ⋅ Qg ⋅ f SW ⋅
⎜
RO + Rg + Rg (int) ⎟⎠
⎝
where
PLDD = the power dissipation from the internal
logic circuitry
PLO = the power dissipation from the gate drive
stage to HO
RO = equivalent output impedance of HO,
typically 10 Ω for the IRS20955S
Rg(int) = the internal gate resistance of the highside MOSFET driver, typically 10 Ω for the
IRS20955S
Rg = external gate resistance of the high-side
MOSFET
Q g = total gate charge of the high- side
MOSFET
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18
IRS20955(S)PbF
PRELIMINARY
NOTES:
1. DIMENSIONING & TOLERANCING PER ANSI Y14.5W-1982
2. CONTROLLING DIMENSION. MILLIMETER
3. DIMENSIONS ARE SHOWN IN MILLIMETER [INCHES]
4. OUTLINE CONFORMS TO JEDEC OUTLINE MS-012AC
5. DIMENSION IS THE LENGTH OF LEAD FOR SOLDERING TO A SUBSTRATE
6. DIMENSION DOES NOT INCLUDE MOLD PROTUSIONS. MOLD PROTUSIONS SHALL NOT
EXCEED 0.15 [.006]
16-Lead SOIC (narrow body)
16-Lead PDIP
www.irf.com
01-6015
01-3065 00 (MS-001A)
19
IRS20955(S)PbF
PRELIMINARY
LOADED TAPE FEED DIRECTION
A
B
H
D
F
C
NOTE : CONTROLLING
DIM ENSION IN M M
E
G
CARRIER TAPE DIMENSION FOR
Metric
Code
Min
Max
A
7.90
8.10
B
3.90
4.10
C
15.70
16.30
D
7.40
7.60
E
6.40
6.60
F
10.20
10.40
G
1.50
n/a
H
1.50
1.60
16SOICN
Imperial
Min
Max
0.311
0.318
0.153
0.161
0.618
0.641
0.291
0.299
0.252
0.260
0.402
0.409
0.059
n/a
0.059
0.062
F
D
C
B
A
E
G
H
REEL DIMENSIONS FOR 16SOICN
Metric
Imperial
Code
Min
Max
Min
Max
A
329.60
330.25
12.976
13.001
B
20.95
21.45
0.824
0.844
C
12.80
13.20
0.503
0.519
D
1.95
2.45
0.767
0.096
E
98.00
102.00
3.858
4.015
F
n/a
22.40
n/a
0.881
G
18.50
21.10
0.728
0.830
H
16.40
18.40
0.645
0.724
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20
IRS20955(S)PbF
PRELIMINARY
ORDER INFORMATION
16-Lead PDIP IRS20955PbF
16-Lead SOIC IRS20955SPbF
16-Lead SOIC Tape & Reel IRS20955STRPbF
SO-16 package is MSL3 qualified.
This product has been designed and qualified for the industrial level.
Qualification standards can be found at IR’s Web Site http://www.irf.com/
WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245 Tel: (310) 252-7105
Data and specifications subject to change without notice 12/11/2006
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21