datasheet for PA74A by Apex Microtechnology

datasheet for PA74A by Apex Microtechnology
EK21
EK21
EK21 PA74
Evaluation Kit for PA74 Pin-Out
INTRODUCTION
This easy-to-use kit provides a platform for the evaluation
of power op amps that use the PA74 pin-out coniguration. It
can be used to analyze a multitude of standard or proprietary
circuit conigurations. In addition, it is lexible enough to do most
standard ampliier test conigurations.
The schematic for 1/2 of the PC board is shown in Figure 2.
The schematic for the other half is identical except part reference designators are primed (i.e. R1 = R1'). Note that all of
the components shown on the schematic will probably not be
used for any single circuit. The component locations on the PC
board (See Figure 3) provide maximum lexibility for a variety
of conigurations. Also included are loops for current probes as
well as connection pads on the edge of the PC board for easy
interconnects.
The hardware required to mount the PC board and the device
under evaluation to the heatsink are included in the kit. Because
of the limitless combination of conigurations and component
values that can be used, no other parts are included in this
kit. However, generic formulas and guidelines are included in
the Apex Microtechnology DATABOOK and this evaluation kit
documentation.
BEFORE YOU GET STARTED
• All Apex Microtechnology ampliiers should be handled using
proper ESD precautions!
• Initially set all power supplies to the minimum operating levels
allowed in the device data sheet.
• Check for oscillations.
• Always use the heatsink included in this kit with thermal grease
or a TW03 and torque the part to the speciied 4-7 in-lbs
(.45-.79 N•M).
• Do not change connections while the circuit is under power.
• Never exceed any of the absolute maximums listed in the
device data sheet.
• Always use adequate power supply bypassing.
• Remember that internal power does not equal load power.
• Do not count on internal diodes to protect the output against
sustained, high frequency, high energy kickback pulses.
Figure 1
PARTS LIST
Part #
HS11
EVAL02
MS03
HWRE01
TW03
Description
Heatsink
PC Board
Mating Socket
Hardware Kit
Thermal Washer
Quantity
1
1
2
1
1 Box/10
HWRE01 contains the following:
4 #8 Panhead Screw
4 #6 x 1.25" Panhead Screw
4 #8 .375" Hex Spacer
4 #6 x 5/16" Hex Nut
4 #8 1.00" Hex Standoff
2 #6 x 1/4" Hex Nut
ASSEMBLY HINTS
The mating sockets included with this kit have recessed
nut sockets for mounting the device under evaluation. This
allows assembly from one side of the heatsink, making it easy
to swap devices under evaluation. The sizes of the stand-offs
were selected to allow proper spacing of the board-to-heatsink
and allow enough height for components when the assembly
is inverted.
ASSEMBLY
1. Insert a #6 x 5/16" hex nut in each of the nut socket recesses
located on the bottom of the mating socket.
2. Insert the socket into the pc board until it is irmly pressed
against the ground plane side of the pc board.
3. Solder the socket in place (see Figure 1). Be sure the nuts
are in the recesses prior to soldering.
4. Mount the PC board assembly to the heatsink using the
stand-offs and spacers included.
5. Apply thermal grease or a TW03 to the bottom of the device
under evaluation. Insert into the mating socket through the
heatsink.
6. Use the #6 x 1.25" panhead screws to mount the ampliier to
the heat sink. Do not overtorque. Recommended mounting
torque is 4-7 in-lbs (.45-.79 N•M).
Mounting precautions, general operating considerations,
and heatsinking information may be found in the Apex Microtechnology DATA BOOK.
NOTE: Refer to HS11 Heatsink in Accessories section
Heatsink
Power Op Amp
Package
#6 Screw
#8 Screw
#8 .375"
Hex Spacer
Recessed Nuts
Teflon Tubing
(2 Opposite Pins
Minimum)
www.apexanalog.com
EK21U
Mating Socket
Copyright © Apex Microtechnology, Inc. 2012
(All Rights Reserved)
PC Board
#8 1.00"
Hex Standoff
OCT 20121
EK21U REVK
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C3
J1
+VS
C6
C4 C5
–VS
R13
R14
R15
R16
R17
C1
C2
C3
C4
C5
C6
C7
C8
C9
C10
C11
C12
D1,2,3,4
C13-16
2
R16
C13
C14
10
C7'
R9'
C9'
C11'
R8'
R15'
R10'
C14'
R11'
10'
R16'
8'
R2'
R4'
7'
R3'
C8'
C6'
6'
-V'
9'
3'
D4'
D2'
D3'
D1'
8
J1'
OUT A'
R6'
C4'
R1'
R5'
C2'
+V'
1'
EVAL02 REV. E
PA74 EVAL.
C7
C9
C11
C14
R8
OUT B
9
8
D2
D4
D3
J1
D1
3
OUT A
R7
C1'
R5
R6
C4
R1
+V
13
2
R14
1
C15
4
-V
R15
8
10
6.00
R9
R2
R4
R3
C8
7
C6
6
OUT B'
R7'
C3'
C1'
2'
C10'
13'
R14'
R13'
1
C15'
4'
C10
R12
9
R15
TOP SIDE
R10
R9
R10
R11
R11
Figure 3.
R13
R8
FUNCTION
Feedback resistor, A side
Input resistor, B side, bridge mode
Feedback resistor, B side
Input resistor, B side
Input resistor, A side
Input bias current measurement (Note 4)
Output current sense resistor or loop for
current probe
Output current sense resistor or loop for
current probe
Input bias current measurement (Note 4)
Noise gain compensation (Note 1)
Resistor divider network for single supply
bias (Note 2)
Resistor divider network for single supply
bias (Note 2)
Noise gain compensation (Note 1)
Input bias current measurement
Input bias current measurement
Resistor divider network for single supply
bias (Note 2)
Resistor divider network for single supply
bias (Note 2)
Input coupling
AC gain set
AC gain or stability (Note 1)
Power supply bypass
Power supply bypass
AC gain or stability (Note 1)
AC gain set
Input coupling
Noise gain compensation (Note 1)
Noise gain compensation (Note 1)
Power supply bypass (Note 3)
Power supply bypass (Note 3)
Flyback protection (Note 5)
Bias node noise bypass (Note 2)
R12'
COMPONENT
R1
R2
R3
R4
R5
R6
R7
R11
TYPICAL COMPONENT FUNCTIONS
8
–VS
R12
C12
R10
D4
C13'
C11
D3
R17'
R17
6
C9
C3
R14
R9
B
R8
C16'
C16
R7
R16
C15
A
B
C13
4
A
R17
R13
R12
3
7
D2
D1
R6
C16
C10
13
C8
R4
C12'
R5
1
C7
R3
+VS
2
C5'
C2
C12
R1
C1
R2
C5
Figure 2
C2
1
8.00
BOTTOM SIDE
EK21U
EK21
BRIDGE MODE OPERATION
There are two types of bridge mode operation that will be
covered in this section; dual (or split) supply and single supply.
The PA74 is well suited for both types of bridge mode operation.
If another vendor’s pin compatible part is to be compared to the
PA74, a close look at output swing and input common mode range
is in order. The features that make the PA74 an excellent choice
for bridge operation are not included in most other ampliiers. A
lack of common mode range may cause permanent damage to
other pin compatible parts and the inability of other ampliiers
to swing close to the supply rails may cause a lack of available
output voltage at the load as well as increase internal dissipation.
The circuit shown in Figure 4 is a dual supply bridge using
the “master-slave” coniguration. Resistors R 6,7,8,9,14,15
and J1 should be shorts. The available output voltage swing
is Vss–(2*Vsat). If operating a PA74A at 3 Amps and 30 Volts
total supply this translates to:
VAB(max) = 30–(2*3.5) = 23
the load. To set the gain of the circuit you must determine the
desired voltage across the load at Vin = full scale. Inserting these
values into the following equation will yield the ratio of R1 to R5.
(VAB /(2*Vin)) = R1/R5
The values of R 1,2,3, and 5 should be chosen such that
input bias current will not cause an error voltage that is unacceptable. Set R2 equal to R3 to conigure the slave ampliier
as a unity gain inverter.
Figure 5 shows a typical single supply bridge circuit for an AC
coupled input signal. DC coupled inputs may require a different
topology to accommodate proper gain and offset terms for a
desired transfer function.
The gain and output voltage capability for the single supply
bridge are determined the same way as the dual supply bridge
(see AN#2). The difference is the bias requirement for the slave
ampliier. The noninverting input of the slave ampliier should
be biased at mid supply, and must be bypassed.
Of course this 23 volts may be applied in either direction across
Figure 4
Dual
Supply
Bridge
J1
+VS
R1
1
R2
R5
C4 C5
D2
D1
R6
A
A
3
R3
+VS
VIN
R9
B
B
R8
R7
D4
D3
C11
Figure 5
Single
Supply
Bridge
2
1
9
R15
R14
C12
–VS
–VS
C1
J1
+VS
R1
R5
R2
C4 C5
R3
+VS
+VS
3
C15
4
EK21U
D2
D1
13
R9
R6
R12
C16
A
A
R7
B
B
R8
R14
R17
R15
D3
D4
3
EK21
HS11 HEATSINK NOTE
The HS11 Heatsink is provided in this evaluation kit to guarantee adequate thermal design through heat removal from the
part under evaluation. Once maximum power dissipation for the
application is determined (refer to “General Operating Considerations” and Application Note 11 in the Apex Microtechnology
DATA BOOK), the inal mechanical design will probably require
substantially less heatsinking.
Apex Microtechnology makes no representation that the use
or interconnection of the circuits described herein will not infringe on existing or future patent rights, nor do the descriptions
contained herein imply the granting of licenses to make, use or
sell equipment constructed in accordance therewith.
NOTES:Refer to the following sections of the Apex Microtechnology DATA BOOK as noted.
1. See Stability section of “General Operating Considerations.”
2. See “Gen. Operating Considerations,” and AN3 “Bridge Circuit Drives.”
3. See Power Supplies section of “General Operating Considerations.”
4. See “Parameter Deinitions and Test Methods.”
5. See Ampliier Protection section of “Gen. Operating Considerations.”
NEED TECHNICAL HELP? CONTACT APEX SUPPORT!
ForallApexMicrotechnologyproductquestionsandinquiries,calltollfree800-546-2739inNorthAmerica.
Forinquiriesviaemail,[email protected]
InternationalcustomerscanalsorequestsupportbycontactingtheirlocalApexMicrotechnologySalesRepresentative.
Toindtheonenearesttoyou,gotowww.apexanalog.com
IMPORTANTNOTICE
ApexMicrotechnology,Inc.hasmadeeveryefforttoinsuretheaccuracyofthecontentcontainedinthisdocument.However,theinformationissubjecttochange
withoutnoticeandisprovided"ASIS"withoutwarrantyofanykind(expressedorimplied).ApexMicrotechnologyreservestherighttomakechangeswithoutfurther
noticetoanyspeciicationsorproductsmentionedhereintoimprovereliability.ThisdocumentisthepropertyofApexMicrotechnologyandbyfurnishingthisinformation,ApexMicrotechnologygrantsnolicense,expressedorimpliedunderanypatents,maskworkrights,copyrights,trademarks,tradesecretsorotherintellectual
propertyrights.ApexMicrotechnologyownsthecopyrightsassociatedwiththeinformationcontainedhereinandgivesconsentforcopiestobemadeoftheinformationonlyforusewithinyourorganizationwithrespecttoApexMicrotechnologyintegratedcircuitsorotherproductsofApexMicrotechnology.Thisconsentdoesnot
extendtoothercopyingsuchascopyingforgeneraldistribution,advertisingorpromotionalpurposes,orforcreatinganyworkforresale.
APEXMICROTECHNOLOGYPRODUCTSARENOTDESIGNED,AUTHORIZEDORWARRANTEDTOBESUITABLEFORUSEINPRODUCTSUSEDFOR
LIFESUPPORT,AUTOMOTIVESAFETY,SECURITYDEVICES,OROTHERCRITICALAPPLICATIONS.PRODUCTSINSUCHAPPLICATIONSAREUNDERSTOODTOBEFULLYATTHECUSTOMERORTHECUSTOMER’SRISK.
ApexMicrotechnology,ApexandApexPrecisionPoweraretrademarksofApexMicrotechnolgy,Inc.Allothercorporatenamesnotedhereinmaybetrademarks
oftheirrespectiveholders.
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Copyright © Apex Microtechnology, Inc. 2012
(All Rights Reserved)
OCTEK21U
2012
EK21U REVK
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