Six-Output 600V MGDs Simplify 3-Phase Motor Drives

Application Note AN-985
Six-Output 600V MGDs
Simplify 3-Phase Motor Drives
Table of Contents
Page
Gate Drive Requirements.....................................................................2
IR213x Block Diagram .........................................................................2
Input Control Logic ...............................................................................3
Protection Circuits and Fault Reporting................................................4
Output Drivers ......................................................................................6
Application Guidelines..........................................................................7
Layout Guidelines ................................................................................8
Specific Applications ............................................................................8
Appendix 1 Component Switches ........................................................10
Traditionally the functions described above have required discrete circuits of some complexity
but International Rectifier’s IR213X series six-channel gate drivers perform all the
requirements for interfacing logic level control circuits to high power MOS-gated devices in
high-side/ low-side switch configurations using up to six devices.
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AN-985
cover
APPLICATION NOTE
AN-985
International Rectifier • 233 Kansas Street, El Segundo, CA 90245
USA
Six-Output 600V MGDs Simplify 3-Phase Motor Drives
1. Gate Drive Requirements
MOS-gated transistors commonly used in motor drives, UPS and converters operating at dc bus voltages up
to 600VDC require voltage drive in order to achieve a saturated “ON” state condition. The drive signal must
have the following characteristics:
1) An amplitude of 10V to 15V.
2) A low source resistance for rapid charge and discharge of the gate capacitance.
3) A floating output so that high side switches can be driven.
In addition to the above requirements the actual driver should be capable of driving combinations of devices
in both low-side and high-side switch configurations. With this in mind the driver should also provide the
following:
1) Low internal power loss at high switching frequency and maximum offset voltage.
2) Accept ground referenced logic level input signals.
3) Protect the power switch from damage by clamping the gate signal to the low state in the event of
gate undervoltage or overvoltage or if the load current exceeds a predetermined peak value.
4) Protect the power switch by clamping the signal to the low state if the signal inputs are
disconnected.
Traditionally the functions described above have required discrete circuits of some complexity but
International Rectifier’s IR213X series six-channel gate drivers perform all the requirements for interfacing
logic level control circuits to high power MOS-gated devices in high-side/ low-side switch configurations
using up to six devices.
2. IR213x Block Diagram
As shown in Figure 1 the I.C. consists of six output drivers which receive their inputs from the three input
signal generator blocks each providing two outputs. The three low-side output drivers are driven directly
from the signal generators L1, L2 and L3 but the high-side drive signals H1, H2 and H3 must be level shifted
before being applied to the high-side output drivers.
An undervoltage detector circuit monitoring the VCC level provides an input to inhibit the six outputs of the
signal generator circuits. In addition, there are individual undervoltage lockout circuits for the high-side
outputs should any of the floating bias supplies fall below a predetermined level.
The ITRIP signal which can be derived from a current sensor in the main power circuit of the equipment
(current transformer, viewing resistor, etc.) is compared with a 0.5volt reference and is then “OR-ed” with
the UV signal to inhibit the six signal generator outputs.
HEXFET® is the registered trademark for International Rectifier Power MOSFETs
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1
INT985
A fault logic circuit set by the UV or ITRIP inputs provides an open drain TTL output for system indication or diagnostics. There
is also an internal current amplifier in the IR2130 and IR2132 that provides an analog signal proportional to the voltage
difference between VSS and VS0. Thus, a viewing resistor in the main power circuit can provide a positive voltage at VS0 and by
suitable feedback resistors the current amplifier can be scaled to generate 0-5Vdc as a function of actual load current (see 2.2.4).
The IR2131 does not have the internal current amplifier.
VB1
INPUT
SIGNAL
GENERATOR
HIN1
H1
L1
HIN2
SET
PULSE
GENERATOR
RESET
LEVEL
SHIFTER
LATCH
DRIVER
HO1
UV
DETECTOR
VS1
HIN3
VB2
LIN1
INPUT
SIGNAL
GENERATOR
LIN2
H2
L2
SET
PULSE
GENERATOR
RESET
LEVEL
SHIFTER
LIN3
LATCH
DRIVER
UV
DETECTOR
HO2
VS2
FAULT
VB3
CLEAR
LOGIC
INPUT
SIGNAL
GENERATOR
FAULT
LOGIC
C
S
H3
L3
SET
PULSE
GENERATOR
LEVEL
RESET
SHIFTER
LATCH
DRIVER
UV
DETECTOR
HO3
VS3
VCC
ITRIP
CURRENT
COMPARATOR
0.5V
DRIVER
LO1
DRIVER
LO2
DRIVER
LO3
UNDERVOLTAGE
DETECTOR
CAO
CURRENT
AMP
-
+
CA-
VSS
VS0
Figure 1. Functional block diagram of the IR2130/2132 drivers.
2.1.
Input Control Logic
A logic low at any of the six inputs causes its corresponding output to go high, as shown in the truth tables (Tables 1 and 2).
Internal 50k pull-up resistors to VCC ensure that all
outputs are low if the inputs are open-circuited.
Inputs are TTL and CMOS compatible with VIH set
at 2.2V and VIL at 0.8V. A 500 nsec input filter
prevents spurious triggering from fast noise pulses.
The input logic circuitry also provides deadtime to
avoid overlap when nearly coincident transitions
take place at the LIN and HIN input pins in the
same channel. This is illustrated in Figure 2.
A further protection against shoot-through currents
in the power devices is provided by shutting down
both high and low outputs if both are
simultaneously commanded "ON" for the IR2130
and IR2132.
LIN1
HIN1
LO1
Tfil
Tdt
HO1z
Tdt
Tfil
INPUT FILTER TIME : Tfil ~ 0.3µ
µs
DEADTIME : Tdt ~ 1.2µ
µs
Figure 2. Input to output timing diagram for IR2130/2132 only
INT985
For some applications such as variable reluctance drives it is necessary to enable the high side and low side outputs
simultaneously. The logic circuitry of the IR2131 allows this (see table 2) and permits any output condition determined only by
the 6 input logic levels.
HIN
1
1
0
0
LIN
1
0
1
0
HO
0
0
1
0
LO
0
1
0
0
Table 1. IR2130, IR2132 Truth table for each input/output pair
HIN
1
1
0
0
LIN
1
0
1
0
HO
0
0
1
1
LO
0
1
0
1
Table 2. IR2131 Truth table for each input/output pair
2.2
Protection Circuits and Fault Reporting
2.2.1
UV Protection
An undervoltage condition on the VCC level, defined as less than 8.9V (as VCC is reduced) and less than 9.3V nominal (as VCC is
increased) causes all outputs to shutdown (see Section 2.2.3).
With VCC at around 9 volts the drivers provide marginally adequate drive voltages to ensure full enhancement of the power
switches for most applications. Separate UV lockout circuits are provided on the three high-side outputs. They also have a 0.4V
hysteresis band with levels of 8.3 volts for a falling bias voltage and 8.7 volts for a rising voltage. Unlike the VCC UV circuit they
inhibit only their particular high-side output and do not affect the operation of any other output.
2.2.2
Current Trip
In the event of a shoot-through current or an output
overload it is desirable to terminate all the output signals
from the driver. This is accomplished through a current
comparator circuit which monitors the voltage drop across
a low side viewing resistor and compares it with a 0.5 volt
reference level. The current comparator output is "OR-ed"
with the VCC UV circuit output (2.2.1) so that a fault
condition of either type causes the fault logic circuit to
actuate.
2.2.3
Fault Logic
VCC
VS INPUT
CAO
OUTPUT
CA VSS
Rf
OP AMP SPEC:
RIN
VSO RANGE: -5V TO 7V
CA- RANGE: 0V TO 7V
CAO RANGE: 0V TO 5.2V
UNITY GAIN: BANDWIDTH = 1 MHz
SLEW RATE: 6V/µ
µ S AND -3.5V/µ
µS
VSS
This circuit consists of a latch which is set by the
conditions described in 2.2.2 and is reset by holding all
three low-side inputs high for more than 10 microseconds
Figure 3. Current Amplifier Operation with Triangular
or by recycling the VCC bias supply. When the fault latch is
Waveform Input
set it produces two output signals. One is used to inhibit all
three input signal generator circuits thus inhibiting all six
outputs. The other output signal appears as a fault indicator which goes low in the presence of a fault condition as defined in
2.2.2. The active low condition can drive an LED fault indicator or external logic circuit.
INT985
2.2.4
Current Sensing in IR2130, IR2132
Using the same current viewing resistor described in 2.2.2 the current sense voltage of 0-0.5V is amplified in the current
amplifier to generate a 0-5V analog function for processing in an external control circuit.
In actual operation the voltage difference between the VS0 and VSS pins forms the input voltage for the noninverting amplifier
although only the positive current (VS0 positive WRT VSS) is measured. Two resistors Rf and RIN set the gain of the amplifier as
shown in Figure 3.
Actual voltage gain is given by the relationship
A=
R f + R IN
R IN
for a gain of 10 with RIN = 1k:
10 =
R f + 1K
1K
Rf + 1K = 10K
Rf = 9K
Power for the current amplifier is supplied from VCC.
The shape of the current seen in the DC link will
depend on the switching topology used for the three
phase bridge. Two such topologies are the "Six Step
Inverter" and the "Pulse Width Modulated Inverter".
Suffice to say that for reasonable load levels at
moderate to high power factors the DC link current will
always be a positive value. Any negative current passed
back through the free wheeling diodes in the bridge due
to the lagging current will be absorbed in the bridge
and not appear in the DC link.
At light or low power factor loads the negative current
levels will begin to exceed the positive demands in the
bridge and a net negative current will flow in the DC
link. The same will occur if the load is caused to
regenerate back into the system.
Input
0.8 Vp-p
0V
Output
4 Vpeak
0V
T = 125 µ sec
F= 8 kHz
Response Delay
12.6 µ sec
Figure 4. Current Amplifier Operation with Triangular
Waveform Input
The output of the amplifier will not provide a negative voltage. This means that any negative current excursions in the DC link
through the current sensing resistor will not appear at the output of the amplifier. This loss of information is further compounded
by a characteristic of the amplifier that is not obvious from the data sheet. A recovery delay exists in the current sense amplifier
operation as the input signal changes from a negative to a positive value.
The loss of negative input signals and the recovery delay of the amplifier is illustrated in Figure 4 where a triangular input was
used as an example. The length of the delay is related to the dv/dt at the zero crossover of the input signal. As described earlier,
negative inputs to the current sense amplifier are possible at light and low power factor loads. These negative excursions of
current will be lost by the current amplifier.
INT985
The recovery delay of the amplifier is due to the Vs0 input pin to the amplifier saturating when a negative voltage is applied. The
charge accumulated requires time to be removed or dissipated before the amplifier will begin to function correctly. The only
method to stop this recovery delay time is to inhibit the Vs0 input voltage from going negative.
The input voltage will generally be of a small
magnitude (less than 1 volt) since it is desirable to
minimize the losses across the current sensing
resistor and not introduce excessive voltages that
will upset the drive circuitry. Such a small voltage
signal is unsuitable for diode clipping.
Figure 5 shows one way of preventing the noninverting input to the amplifier from going
negative. If a differential amplifier is used with a
voltage reference to shift the effective zero current
reference input signal, the output will appear as an
amplified version of the input signal, offset by some
positive voltage.
Vref
R3
Vsense
Another possibility, suitable for lower power
applications is shown in Figure 7.
Vs
+
Vca
Ouput
Rsense
Vca -
R2
The relevant calculations for the selection of
components for the given circuit are given in
Appendix 1. It can be seen that the choice of
components is limited by the total amount of
resistance allowed in the gate loop, and the
maximum current that can be sourced by the
internal amplifier.
For those motor drives that do not use co-pak
IGBTs, it is a relatively simple operation to
prevent the negative component of dc link current
from flowing into the current sensing resistor. The
circuit in Figure 6 shows an implementation of
this technique in a bridge that utilizes IGBTs.
When MOSFETS are used as the switching
devices an additional diode is required in series
with each MOSFET to negate the internal bodydrain diode.
R4
+
Figure 5. Different Amplifier with Voltage Offset
IR2130
Lout1
Amplitier
Output
Vco
Lout2
VcaVss
Lout3
Vs
Rshunt
DC Return
Figure 6. Measurement of Positive Current Components in the
DC Link
Negative current components are blocked by the shunt resistor diode and forced through a second rated parallel diode. Schottky
diodes are suitable for this application.
Note: The IR2131 does not have an analog current amplifier.
2.3
Output Drivers
The International Rectifier 213X family has six output drivers, three referenced to VS0 and three floating drivers capable of
operating with offset voltages up to 600V positive to VS0. All outputs have inverted logic, i.e., they go positive when the
corresponding LIN or HIN goes low unless there is an over-riding fault condition (see 2.2.3). The output current is typically
0.25A on the positive edge and 0.5A on the negative edge of the output pulse, and when driving a typical MOS gate of 1000pF
results in a maximum risetime of 100 nsec and falltime of 50 nsec.
Figure 2 shows the time relationship between input and output waveforms for the IR2130, IR2132. The input filter delay is
typically 300 nsec and the deadtimes are 1.5 msec minimum and 2.0 msec maximum for the IR2130 and 700 ns for the IR2131.
INT985
5A
2OCTQO45
7815
115V
AC
INPUT
+
100µ
µF
50V
+
11DF4
ST-3-1444
50µ
µF
250V
+5V
7805
11DF4
+15V
11DF4
16
1
V+
2
CLR Q1
D2
8
1K
V+
RST
100K
4
Q3
RESET
5
10
6
1
5.1K
2
3
60Hz
VCC
VB1
HIN1
HO1
27
+
HIN2
4 HIN3
Q2
VS1
7
5µ
µF +
3
5
DIS
Q1
VB2
LIN1
4
6
D1
LIN2
HO2
+
555 360Hz
11 FAULT
IR2130
Q3
3
6
9 CLK Q2 7 LED
250µ
µ 7
TH V0
LIN3
VS2
2
5
12
8
TR
D3
FAULT VB3
CONT
1K
G
G
9
ITRIP H03
1
10
CAO
9.1K
0.022µ
µF
0.01µ
µF
VS3
11
CA12
1K
VSS
LO1
13
VS0
14
LO3
LO2
20Ω
Ω
0.33Ω
Ω
SET
74175N
28
10
µF
26
60 Hz
24
φA
23
+
22
10µ
µF
φB
20
19
+
10µ
µF
18
φC
16
15
ITRIP
I0
6 x IRGBC20S IGBTS
Figure 7. Three-phase six-step motor drive and 6 x HFA04TB60 HEXFRED diodes
2.3.1
Low Side Output Drivers
Because of the current amplifier requirements and to increase noise immunity between the power ground and the ground
reference of the logic circuits, the VS0 to VSS offset voltage capability is bi-directional at ±5V.
2.3.2
High-Side Output Drivers
When driving inductive loads the VS1, VS2 and VS3 terminals are driven negative with respect to VS0 as inductive energy is
commutated by the diodes across each low side power switch. For this reason the total offset capability is specified as -5V to
+600V. The -5V spec is needed to accommodate instantaneous diode drops due to forward recovery as well as inductive effects of
high current wiring, etc.
As previously mentioned in Section 2.2.1, undervoltage lockout is provided for each high side driver to prevent marginal
operation if the bootstrap capacitors become discharged. This problem occurs more frequently in six-step brushless dc drives at
extremely low speed or stall conditions and could result in high dissipation operation of the upper power switches if the UV
lockout circuits were absent.
During long pulses, with the bootstrap capacitors supplying all the energy for the floating drivers, the capacitors gradually
discharge until at 8.3 volts nominal the UV detector shuts down the output and prevents the power switch from overdissipating.
If long pulses have to be delivered to the outputs the shutdown condition can be avoided by:
1) Using larger bootstrap capacitors.
2) Refreshing bootstrap charge by momentarily turning off and reapplying input command pulse.
3) Providing continuous bias from floating dc power supplies.
INT985
3.0
APPLICATION GUIDELINES
3.1
Bootstrap and Decoupling Capacitors
Three bootstrap capacitors are required to supply power for the floating outputs of the driver, the values of which are a function
of the gate charge requirements of the power switch and the maximum power switch "ON" times.
The internal floating driver current also must be supplied from the bootstrap capacitors. After all these energy requirements have
been met there must still be enough charge remaining on CBOOT to avoid UV shutdown (8.3V nominal).
Example:
What is the maximum tON under the following conditions?
If VCC = 15V and the charging of the bootstrap capacitor occurs when VS0 = -1.0V and VF of the bootstrap diode is 1.0V we have
a net voltage on CBOOT of 15Vdc. Let us also assume that we are using a #5 size power switch such as an IRF450 or IRGPC50U
either of which require a total gate charge of around 0.12 mC and that we want to maintain a CBOOT of 0.1pF at a minimum
voltage of 10Vdc:
during discharge ∆v = 5V
-6
QAVAIL = CV = 0.1 X 10 X 5 Volts = 0.5 mC
QREQD = 0.12 mC
(See data sheet IRF450
or IRGPC50U)
Hence, having supplied the gate charge, the gate voltage is 13.8 V ( 0.38 mC). From the point on, a constant leakage current IQBS
= 15 µA discharges the bootstrap capacitor. The time it takes for the bootstrap capacitor to discharge to 10 V can be calculated
as follow:
∆t = C x ∆v / I = 0.1 µF x 3.8 V /15 µA = 25 ms.
The above calculation neglects the leakage current in the bootstrap diode, which must be a fast recovery type to avoid discharging
CBOOT as the diode starts to block voltage.
In practice, as indicated in INT-978 Section 5, it is not advisable to use a bootstrap capacitor smaller than 0.47 µF
In terms of decoupling requirements, a capacitor at least 10X the value of CBOOT is required from VCC to VSS to provide adequate
charging current for CBOOT and also to minimize voltage transients on the VCC supply resulting from these currents.
3.2
Power Dissipation
The drivers have a "fault" output on pin 8 which is really an open drain MOSFET with its source connected to VSS (pin 12) . The
intrinsic diode of this MOSFET has a negative temperature coefficient of Vf almost exactly equal to -0.002V/°C. Thus we have a
"built-in" thermometer to monitor die temperature using a -1mA constant current supply to pin 8.
Actual die temperatures are dependent on frequency of operation, the offset voltage (HVDC bus voltage) and the capacitance of
the MOS-gated power switches being driven. The value of the series gate resistors also determines overall switch loss but has
little effect on the driver temperature. A detailed analysis of losses in MGDs can be found in INT-978 Section 4.
Curves of junction temperature using various 500-volt MOSFETs and gate resistors versus switching frequency are to be found in
the individual date sheets for the IR213X series of MOS gate drivers.
INT985
4.0
LAYOUT GUIDELINES
The driver forms the interface between the low level logic circuitry and the high power switching devices. It follows then that
signal grounds and high power returns should not be mixed together indiscriminately but should follow carefully formulated
rules so that crosstalk problems can be avoided. Some detailed rules are contained in Sections 5 and 6 of INT-978.as follows:
1) The gate drive returns from the three low side devices should be run to the VS0 pin with separate and independent
tracks to avaid crosstalk between the different legs of the inverter
2) Common mode currents arising from wiring layouts that allow load currents to flow in signal return circuits must
be avoided.
3) Load current loop size must be small to minimize circuit inductance.
4) High current buses must be adequately decoupled at the switching point to minimize inductive spiking.
5) Adequate shielding between high voltage, high dv/dt points and low level signal circuits must be provided.
6) Transformer designs must minimize voltage gradients between adjacent windings and to the core to prevent
capacitively coupled currents from flowing in sensitive signal circuits.
7) Power switch dv/dt values should be kept as low as possible consistent with overall system efficiency so that induced
bus voltage spikes are minimized.
Contrary to generally accepted theory that faster switching is better, there are several conflicting requirements in the interface
between the driver and the driven power device:
1) If the distance between driver and power stage is more than a couple of inches, the drive signal should be run in a
twisted pair routed directly to the gate and source (or emitter) of the power device.
2) Drivers such as the IR2130 have low impedance outputs and consequently cause very fast switching of power
MOSFETs. Severe ringing occurs at the switching transistors resulting in unwanted RFI generation and possible
dv/dt failure of the power MOSFETs. A quarter-watt non-inductive series gate resistor of about 10 to 33 Ohms
usually provides sufficient roll-off with CISS to damp out the ringing. With small HEXFETs (die sizes 1 to 3) the
resistor value should be increased from about 30 to 50 Ohms.
3) In motor drive circuits where the load inductance is high, the motor current is commutated by diodes across the
power switches when the switches are "OFF." As the opposite switch in a particular bridge leg is turned "ON" it
must pull the conducting commutation diode out of conduction through its reverse recovery condition. A spike of
current occurs at this time which causes ringing and RFI generation. The magnitude of the current spike can be
reduced by the use of the series gate resistor described in (2) above.
5.
SPECIFIC APPLICATIONS
5.1
Six-Step 3-Phase Motor Drive
Figure 4 shows a typical 3-phase non-regulated motor drive in which the IR2130 supplies all the gate drive signals for the highside and low-side IGBTs. The IR2130 is operated from a 15-volt dc supply from a 3-terminal regulator and the inputs are derived
from a six-step ring counter with its input signal supplied by a 555 astable multi-vibrator operating at 360 Hertz. The dc bus for
the six-step inverter is supplied off-line by rectifying the 115-volt ac input and filtering it with a 50 microfarad 250-volt
capacitor.
Motor current is sensed by a series viewing resistor in the negative bus with a 20-Ohm pot across the resistor so that a voltage
proportional to load current is delivered to the ITRIP pin 9 of the IR2130. Also, a dc voltage proportional to motor current is
available at pin 10. This uses a 9KΩ feedback resistor and a 1KΩ input resistor on pin 11, the inverting input to the current
amplifier.
INT985
5.2
A 3-Phase Variable Reluctance Drive Using IR2131
Figure 6 shows a variable reluctance motor
drive using IGBT's and the IR2131 MOS
Gate Driver. High side and low side outputs
are simultaneously provided to drive each set
of motor phase coils.
2V
1V
2mS
OUTPUT VOLTAGE
FROM CURRENT
AMPLIFIER (PIN 10).
2V/DIV. LIGHT LOAD
- 0 (0.5A pk)
The inputs can be simple logic levels spaced
120 electrical degrees apart or can be pulse
width modulated to control motor torque.
LINE TO LINE
OUTPUT VOLTAGE
- 0 TO 3 PHASE MOTOR
(APPROX 60 Hz).
100V/DIV.
The values of the bootstrap capacitors are
selected to prevent undervoltage lockout at
the minimum frequency of operation.
100V
Typically when the minimum frequency is
around 30Hz, 10mF electrolytic capacitors
Figure 8. Six-step motor drive waveforms
are used. They must be selected for low
ESR/ESL particularly when large power
switches are used as the peak demand currents can be fairly high.
When starting with the bootstrap capacitors discharged, the first input commands are used to charge them and subsequent
commands provide rotational power for the motor. To avoid this problem, the bootstrap capacitors can be pre-charged by
connecting high value resistors across the 3 low side power switches. With the bootstrap pre-charged, all input logic signals
provide rotational inputs to the motor.
+15V
V+ POWER
28
VB1
1 VCC
27
HO1
2 HIN1
26
3 HIN2 VS1
4
VB2 24
HIN3
23
HO2
5
LIN1
6
V 22
LIN2 S2
7
VB3 20
LIN3
HO3 19
INPUTS
1
2
3
FAULT
LED
250 µ F
5.1K 8
+ 485mV TRIP
15V
RETURN
VS3
φ2
18
φ3
9 ITRIP
1K
LOGIC
GND
FAULT
φ1
12 V
LO1 16
13 SS
14 COM LO2 15
LO3
+
SET
ITRIP
CURRENT SENSE
SINGLE POINT CONNECTION BETWEEN LOGIC GND AND POWER RETURN
Figure 9. Three-phase variable reluctance motor drive
5.3
General Considerations Using MOS Gate Drivers
POWER
RETURN
INT985
Although the IR213X family of drivers can considerably simplify 3-phase motor drives there are some pitfalls to be avoided.
1) The VS1, V S2 and V S3 pins have a maximum specified rating of only -5Vdc. In high current drives it is quite
common for inductive spike voltages to exceed -5V because of stray inductances, diode forward recovery problems
etc. We recommend techniques as described in AN-978 Sec. 6 to address this problem.
2) High current motor drives can also generate ground bus currents which are sometimes severe enough to disrupt
logic circuits and cause mis-commutation of the power switches. This usually results in catastrophic failure of the
entire drive. To combat this we recommend the use of high speed optical couplers as shown in Figure 7. Using this
technique, the power return and logic grounds are completely isolated from one another (see Figure 7).
Appendix 1 Component Selection
150pF
680Ω
Ω
150pF
2
4
1) The maximum value of resistor that can be
inserted in the gate return path is 47
Ohms. Larger values than this may affect
the switching performance of the device.
2) The maximum output current of the amplifier is 2mA under worst case conditions.
680Ω
Ω
150pF
3
8
HCPL2531
1
2
4
680Ω
Ω
150pF
3
1
Vcao / Vs0 = 1 + R1/R2
(1)
680Ω
Ω
150pF
2
4
680Ω
Ω
3
6
5
7
6
VCC
HIN1
3
7
FAULT
LED
47µ
µF
TANT
HIN2
4
HIN3
5
LIN1
6
LIN2
7
LIN3
8
FAULT
9
ITRIP
10
CAO
11
CA
5
SIGNAL POWER
The signal at the VS0 pin may be defined by the
equation:
12
13
VSS
VS0
LO3
ISOLATION BARRIER
Vs0 = Vsense + (Vref - Vsense) * R4 / (R3 + R4)
(2)
Combining equations (1) and (2) gives:
IR2130
1
5
8
HCPL2531
Consider the circuit configuration shown in Figure 2.
The gain of the non-inverting amplifier stage is:
5.1KΩ
Ω
6
8
1
680Ω
Ω
150pF
7
2
HCPL2531
When selecting components to use with the internal
current amplifier the following design guidelines
should be followed.
Figure 10. Recommended opto-isolated input circuit to the
IR2130
Vcao = Vsense (l + R1/R2) + [(Vref - Vsense) * R4 / (R3 + R4)] * (1 + R1/R2)
If the conditions R1 = R3 and R2 = R4 are true, then the last equation collapses to:
Vout = Vref + Vsense * R1/R2
Using the design guidelines sets the range of resistor values that may be chosen. The 2mA current limit sets a minimum for the
resistance sum R1 + R2. -This limit is defined by:
Ilimit = Vcao(max) / (Rl + R2); Ilimit = 2mA, Vcao(max) = 5V.
This means that R1 + R2 > 2.5 kOhm. R2 is limited to 47 Ohms and R1 > 2.45 kOhm. This gives a gain in the circuit of R1/R2
= 52. If the output of the amplifier is in the range [0;+5V], then the offset could be 2.5V, giving an allowable output voltage
variation of +/-2.5V. The maximum variation of the input voltage is thus +/-50mV.
INT985
This small signal level is possible with commercially available shunts that are low inductance to reduce noise from power device
switching. It does mean however that the internal current trip function of the IR2130 cannot be used, as it has an internal 0.5V
trip point. Care should be taken when using small input signal levels as the data sheet specification for the amplifier offset
voltage is 10mV. An offset adjustment may need to be included in the circuit.
FIGURE CAPTIONS FOR INT-985
Figure No.
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Title
Functional block diagram of the IR2130/2132 drivers
Input to output timing diagram for IR2130/2132 only
Current feedback amplifier connection
Current Amplifier Operation with Triangular Waveform Input
Differential Amplifier with Voltage Offset
Measurement of Positie Current Components in the DC Link
Three-phase six-step motor drive and 6 x HFA04TB60 HEXFRED diodes
Six-step motor drive waveforms
Three-phase variable reluctance motor drive
Recommended opto-isolated input circuit to the IR2130