INTERSIL HIP5600IS2

HIP5600
®
WN
ITHDRA
PART W BSOLETE
SS O
PROCE
IGNS
W DES
N
NO E
September 1998
File Number
Thermally Protected High Voltage Linear
Regulator
Features
The HIP5600 is an adjustable 3-terminal positive linear
voltage regulator capable of operating up to either 400VDC
or 280VRMS. The output voltage is adjustable from 1.2VDC
to within 50V of the peak input voltage with two external
resistors. This high voltage linear regulator is capable of
sourcing 1mA to 30mA with proper heat sinking. The
HIP5600 can also provide 40mA peak (typical) for short
periods of time.
• Operates from 50VRMS to 280VRMS Line
Protection is provided by the on chip thermal shutdown and
output current limiting circuitry. The HIP5600 has a unique
advantage over other high voltage linear regulators due to its
ability to withstand input to output voltages as high as
400V(peak), a condition that could exist under output short
circuit conditions.
Common linear regulator configurations can be implemented
as well as AC/DC conversion and start-up circuits for switch
mode power supplies.
The HIP5600 requires a minimum output capacitor of 10µF
for stability of the output and may require a 0.02µF input
decoupling capacitor depending on the source impedance. It
also requires a minimum load current of 1mA to maintain
output voltage regulation.
All protection circuitry remains fully functional even if the
adjustment terminal is disconnected. However, if this
happens the output voltage will approach the input voltage.
3270.7
• Operates from 50VDC to 400VDC
• UL Recognized
• Variable DC Output Voltage 1.2VDC to VIN - 50V
• Internal Thermal Shutdown Protection
• Internal Over Current Protection
• Up to 40mA Peak Output Current
• Surge Rated to ±650V; Meets IEEE/ANSI C62.41.1980
with Additional MOV
CAUTION: This product does not provide isolation from AC
line.
Applications
• Switch Mode Power Supply Start-Up
• Electronically Commutated Motor Housekeeping Supply
• Power Supply for Simple Industrial/Commercial/Consumer
Equipment Controls
• Off-Line (Buck) Switch Mode Power Supply
Ordering Information
PART
NUMBER
TEMP. RANGE
PACKAGE
HIP5600IS
-40oC to +100oC
3 Lead Plastic SIP
HIP5600IS2
-40oC to +100oC
3 Lead Gullwing Plastic
SIP
Pinouts
HIP5600 (TO-220)
TOP VIEW
TAB ELECTRICALLY
CONNECTED
TO VOUT
HIP5600 (MO-169)
TOP VIEW
VOUT
63
VIN
VOUT
VIN
ADJ
VOUT
ADJ
HIP5600
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright © Intersil Americas Inc. 2002. All Rights Reserved
HIP5600
Functional Block Diagram
HIP5600
RECTIFIER FOR
AC OPERATION
PASS
TRANSISTOR
SHORT-CIRCUIT
PROTECTION
VOUT
-
VIN
-
+
+
RF1
BIAS
NETWORK
C2
THERMAL
SHUTDOWN
-
C1
FEEDBACK
OR CONTROL
AMPLIFIER
+
RF2
+
VOLTAGE
REFERENCE
-
ADJ
Schematic Diagram
VIN
R1
D2
D1
D4
Q1
R2
Q2
D3
R3
Q11
D7
R12
Q12
D8
Q4
R13
D9
R4
Q9
D6
Q5
R11
R5
D5
Q14
C1
R7
R14
Q3
Q6
Q10
R8
R6
R15
Q8
Q7
R10
R9
ADJ
FIGURE 1.
64
Q13
VOUT
HIP5600
Absolute Maximum Ratings
Thermal Information (Typical)
Input to Output Voltage, Continuous . . . . . . . . . . . . +480V to -550V
Input to Output Voltage, Peak (Non Repetitive, 2ms) . . . . . . . ±650V
Junction Temperature. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +150oC
ADJ to Output, Voltage to ADJ . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±5V
Storage Temperature Range . . . . . . . . . . . . . . . . . -65oC to +150oC
Lead Temperature (Soldering 10s). . . . . . . . . . . . . . . . . . . . +265oC
Thermal Resistance
Plastic SIP Package . . . . . . . . . . . . . .
θJA
60oC/W
θJC
4oC/W
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation
of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
Operating Conditions
Operating Voltage Range . . . . . . . . . . . . . . 80VRMS to 280V RMS or
50V DC to 400VDC
Operating Temperature Range . . . . . . . . . . . . . . . .-40oC to +100oC
Electrical Specifications Conditions VIN = 400VDC, IL = 1mA, CL = 10µF, VADJ = 3.79V, VOUT = 5V (Unless Otherwise Specified) Temperature = Case Temperature.
PARAMETER
CONDITION
TEMP
MIN
TYP
MAX
UNITS
INPUT
Input Voltage
DC
Full
50
-
400
V
Max Peak Input Voltage
Non-Repetitive (2ms)
Full
-
-
±650
V
Input Frequency (Note 1)
Full
DC
-
1000
Hz
Bias Current (IBIAS Note 2)
Full
0.4
0.5
0.6
mA
+25oC
50
65
80
µA
Full
-
+0.15
-
µA/oC
+25oC
-
-215
-
nA/mA
+25oC
1.07
1.18
1.30
V
Full
-
-460
-
µV/oC
+25oC
-
9
14.5
µV/V
Full
-
9
29
µV/V
+25oC
-
3
5
mV/mA
Full
-
3
6
mV/mA
REFERENCE
IADJ
IADJTC (Note 1)
IL = 1mA
IADJ LOAD REG (Note 1)
IL = 1mA to 10mA
VREF (Note 3)
VREF TC (Note 1)
IL = 1mA
Line Regulation
VREF LINE REG
50VDC to 400VDC
Load Regulation
VREF LOAD REG
IOUT = 1mA to 10mA
PROTECTION CIRCUITS
Output Short Circuit Current Limit
V IN = 50V
+25oC
35
-
45
mA
Thermal Shutdown TTS
(IC surface, not case temperature. Note 1)
VIN = 400V
-
127
134
142
oC
Thermal Shutdown Hysteresis (Note 1)
VIN = 400V
-
-
34
-
oC
NOTES:
1. Characterized not tested
2. Bias current ≡ input current with output pin floating.
3. VREF = VOUT - VADJ
65
HIP5600
Application Information
Introduction
HIP5600
VIN
ADJ
AC/DC
VOUT
In many electronic systems the components operate at 3V to
15V but the system obtains power from a high voltage
source (AC or DC). When the current requirements are
small, less than 10mA, a linear regulator may be the best
supply provided that it is easy to design in, reliable, low cost
and compact. The HIP5600 is similar to other 3 terminal regulators but operates from much higher voltages. It protects
its load from surges +250V above its 400V operating input
voltage and has short circuit current limiting and thermal
shutdown self protection features.
VREF
IADJ
= (V
REF
RF2
3.3V
3.6k
5.6k
4.9V
2.7k
7.5k
12.0V
1.8k
15k
14.8V
1.1k
12k
VOUT
AC/DC
The HIP5600 provides a temperature independent 1.18V
reference, VREF , between the output and the adjustment
terminal (V REF = VOUT - VADJ). This constant reference
voltage is impressed across RF1 (see Figure 2) and results
in a constant current (I1) that flows through RF2 to ground.
The voltage across RF2 is the product of its resistance and
the sum of I1 and IADJ. The output voltage is given in Equations 1(A, B).
OUT
RF1
RF2
Output Voltage
V
I1
RF1
VOUT(NOMINAL)
RF1 + RF2
( RF2 )
) ------------------------------ + I
ADJ
RF1
RF1 + RF2
= ( 1.18 ) × ------------------------------ + 65µA ( RF2 )
V
OUT
RF1
(EQ. 1A)
FIGURE 2.
Example: Given: VIN = 200VDC , VOUT = 15V, IOUT =
2mA to 12mA, θSA = 10oC/W, RF1 = 1.1kΩ 5% low, RF2 =
12kΩ 5% high, ∆IOUT equals 10mA and ∆Temp equals
+60 oC (ambient temperature +25oC to +85oC). The worst
case ∆VOUT for the given conditions is -1.13V. The shift in
VOUT is attributed to the following: -1.55V manufacturing tolerances, +1.33V external resistors, -0.62V load regulation
and -0.29V temperature effects.
Regulator With Zener
(EQ. 1B)
VOUT = 1.18 + VZ
HIP5600

RF1

VIN
VOUT
∆RF2
RF 1 + RF2
∆V OUT = ∆V T REF  -------------------------- + ∆I T ADJ RF2 + I A DJ RF 2 -------------
ADJ
Error Budget
RF2
R F2 ∆R F2 ∆RF1
+ V RE F  ----------  -------------- – --------------
 R F1  R F2
R F1 
(EQ. 2A)
Where;
VREF
IADJ
T
∆V RE F ≡ ∆V REF + V REF
LOA DREG
( ∆I OUT ) + V REF TC ( ∆Temp )
+V
TC ( θ
) ∆( IOUT ⋅ V IN ) + V
REF
SA
REFLINEREG
(EQ. 2B)
∆I T ADJ ≡ ∆I ADJ + I A DJ
+I
ADJ
TC ( θ
LO ADRE G
SA
( ∆I OUT ) + IADJ TC ( ∆Te mp )
) ∆( I OUT ⋅ V IN )
Note:
(EQ. 2C)
∆RFx = % tolerance of resistor x
--------------RFx
Equations 2(A,B,C) are provided to determine the worst
case output voltage in relation to; manufacturing tolerances
(∆VREF and ∆IREF),% tolerance in external resistors
(∆RF1/RF1, ∆RF2/RF2), load regulation (VREF LOAD REG ,
IADJ LOAD REG ), line regulation (VREF LINE REG) and the
effects of temperature (VREFTC, IREFTC), which includes
self heating (θSA).
66
AC/DC
I1
RF1
VOUT
VZ
VOUT
VZ
3.7V
2.5V
5.1V
3.9V
10.3V
9.1V
12.2V
11V
16.2V
15V
RF1 = 10k
AC/DC
FIGURE 3.
The output voltage can be set by using a zener diode (Figure
3) instead of the resistor divider shown in Figure 2. The
zener diode improves the ripple rejection ratio and reduces
the value of the worst case output voltage, as illustrated in
the example to follow. The bias current of the zener diode is
set by the value of RF1 and IADJ.
The regulator / zener diode becomes an attractive solution if
ripple rejection or the worst case tolerance of the output voltage is critical (i.e. one zener diode cost less than one 10µF
capacitor (C3) and one 1/4W resistor RF2). Minimum power
dissipation is possible by reducing I1 current, with little effect
on the output voltage regulation. The output voltage is given
in Equation 3.
Equations 4(A,B, C) are provided to determine the worst
case output voltage in relation to; manufacturing tolerances
HIP5600
= V REF + V Z
(EQ. 3)
Error Budget
HIP5600
REF
TC ( θ
SA
) ∆( I OUT ⋅ V IN ) + V
REFLINEREG
∆V T Z ≡ V Z to l er an ce ( V Z ) + V Z TC ( ∆Te mp )
RS
(EQ. 4B)
I1
RF1
VREF
(EQ. 4C)
of HIP5600 and the zener diode (∆VREF and ∆Vz), load regulation of the HIP5600 (VREF LOAD REG), and the effects of
temperature on the HIP5600 and the zener diode (VREFTC,
VZTC).
Example: Given: VIN = 200V, V OUT = 14.18V (VREF =
1.18V, VZ = 13V), ∆VZ = 5%, VZTC = +0.079%/ °C (assumes
1N5243BPH), ∆IOUT equal 10mA and ∆Temp equal
+60 oC. The worst case ∆VOUT is 0.4956V. The shift in
VOUT is attributed to the following: -0.2 (HIP5600) and 0.69
(zener diode).
The regulator/zener diode configuration gives a 3.5%
(0.49/14.18) worst case output voltage error where, for the
same conditions, the regulator/resistor configuration results
in an 7.5% (1.129/15) worst case output voltage error.
External Capacitors
IADJ
An optional bypass capacitor (C3) from VADJ to ground
improves the ripple rejection by preventing the ripple at the
Adjust pin from being amplified. Bypass capacitors larger
than 10µF do not appreciably improve the ripple rejection of
the part (see Figure 20 through Figure 25).
VREF
I1
RF1
VOUT
IADJ
AC/DC
(B)
FIGURE 4.
VOUT
RF2
AC/DC
Protection Diodes
The HIP5600, unlike other voltage regulators, is internally
protected by input diodes in the event the input becomes
shorted to ground. Therefore, no external protection diode is
required between the input pin and the output pin to protect
against the output capacitor (C2) discharging through the
input to ground.
If the output is shorted in the absence of D1 (Figure 5), the
bypass capacitor voltage (C3) could exceed the absolute
maximum voltage rating of ±5V between VOUT and VIN .
Note; No protection diode (D1) is needed for output voltages
less than 6V or if C3 is not used.
A minimum10µF output capacitor (C2) is required for stability
of the output stage. Any increase of the load capacitance
greater than 10µF will merely improve the loop stability and
output impedance.
VIN
HIP5600
ADJ
A 0.02µF input decoupling capacitor (C1) between VIN and
ground may be required if the power source impedance is
not sufficiently low for the 1MHz - 10MHz band. Without this
capacitor, the HIP5600 can oscillate at 2.5MHz when driven
by a power source with a high impedance for the 1MHz 10MHz band.
RS
RF2
(A)
AC/DC
VIN
ADJ
( ∆I OUT ) + V REF TC ( ∆Temp )
VOUT
LOADREG
VIN
≡ ∆V REF + V RE F
AC/DC
C1
0.02µF
D1 PROTECTS AGAINST C3
DISCHARGING WHEN THE
OUTPUT IS SHORTED.
VIN
+V
REF
ADJ
∆VT
HIP5600
(EQ. 4A)
∆V OUT = ∆V T REF + ∆V T Z
VOUT
OUT
VOUT
V
+ VOUT
RF1
C3
10µF
RF2
D1
C2
10µF
FIGURE 5. REGULATOR WITH PROTECTION DIODE
Load Regulation
Selecting the Right Heat Sink
For improved load regulation, resistor RF1 (connected
between the adjustment terminal and VOUT) should be tied
directly to the output of the regulator (Figure 4A) rather than
near the load Figure 4B. This eliminates line drops (RS) from
appearing effectively in series with RF1 and degrading regulation. For example, a 15V regulator with a 0.05Ω resistance
between the regulator and the load will have a load regulation due to line resistance of 0.05Ω x ∆IL. If RF1 is connected near the load the effective load regulation will be 11.9
times worse (1+R2/R1, where R2 = 12k, R1 = 1.1k).
Linear power supplies can dissipate a lot of power. This
power or heat must be safely dissipated to permit continuous
operation. This section will discuss thermal resistance and
show how to calculate heat sink requirements.
67
Electronic heat sinks are generally rated by their thermal
resistance. Thermal resistance is defined as the temperature
rise per unit of heat transfer or power dissipated, and is
expressed in units of degrees centigrade per watt. For a particular application determine the thermal resistance (θSA)
which the heat sink must have in order to maintain a junction
temperature below the thermal shut down limit (TTS).
HIP5600
A thermal network that describes the heat flow from the integrated circuit to the ambient air is shown in Figure 6. The
basic relation for thermal resistance from the IC surface, historically called “junction”, to ambient (θJA) is given in Equation 5. The thermal resistance of the heat sink (θSA) to
maintain a desired junction temperature is calculated using
Equation 6.
Example,
Given: VIN = 400VDC
VOUT = 15V
ILOAD = 15mA
θJC = 4.8oC/W
TTS = +127οC
IADJ = 80µA
TA = +50oC
RF1 = 1.1k
VREF = 1.18V
P = 6.2W = (VIN - VOUT)(IIN )
PD
I
TJ = JUNCTION
θJC
TC = CASE
Solution:
θSA
HEAT SINK
°
 C
 --------
 W
∴
θ SA + θ
CS
≈θ
T TS – T A
-–θ
JC
SA = --------------------------P
Use Equation 6,
(EQ. 7)
(EQ. 8)
(EQ. 5)
The selection of a heat sink with θSA less than +7.62oC/W
would ensure that the junction temperature would not
exceed the thermal shut down temperature (TTS) of
+127×oC. A Thermalloy P/N7023 at 6.2W power dissipation
would meet this requirement with a θSA of +5.7×oC/W.
(EQ. 6)
Operation Without A Heatsink
Where:
and
LOAD
°C
127 ° C – 50 ° C
θ SA = ------------------------------------------- – 4.8 ° C = 7.62 -------6.2
W
FIGURE 6.
θ JA = θJC + θ CS + θ SA
RF1
–T
T
TS
A
θ SA = ---------------------------- – θ JC
P
TA = AMBIENT AIR
θ JA = ---------------------P
ADJ
V REF
+ ------------------- + I
Find:
Proper heat sink to keep the junction temperature
of the HIP5600 from exceeding TTS (+127oC).
θCS
TS = HEAT SINK
TJ – T A
IN
≡I
T = T
J
TS
Where:
θJA = (Junction to Ambient Thermal Resistance) The sum of
the thermal resistances of the heat flow path.
θJA = θJC + θCS + θSA
TJ = (Junction Temperature) The desired maximum junction temperature of the part. TJ = TTS
TTS = (Thermal Shutdown Temperature) The maximum
junction temperature that is set by the thermal protection circuitry of the HIP5600
(min = +127oC, typ = +134oC and max = +142oC).
θJC = (Junction to Case Thermal Resistance) Describes the
thermal resistance from the IC surface to its case.
θJC = 4.8oC/W
θCS = (Case to Mounting Surface Thermal Resistance) The
resistance of the mounting interface between the
transistor case and the heat sink.
For example, mica washer.
θSA = (Mounting Surface to Ambient Thermal Resistance)
The resistance of the heat sink to the ambient air.
Varies with air flow.
The package has a θJA of +60oC/W. This allows 0.7W
power dissipation at +85oC in still air. Mounting the HIP5600
to a printed circuit board (see Figure 39 through Figure 41)
decreases the thermal impedance sufficiently to allow about
1.6W of power dissipation at +85oC in still air.
Thermal Transient Operation
For applications such as start-up, the HIP5600 in the TO-220
package can operate at several watts -without a heat sinkfor a period of time before going into thermal shutdown.
PD = I IN (VIN - VOUT)
TJ = JUNCTION
0.6θJC
CD
DIE/PACKAGE INTERFACE
0.4θJC
0.5C P
TS = HEAT SINK
OR CASE
θSA
TA = AMBIENT AIR
CS + 0.5CP
TA = Ambient Temperature
P = The power dissipated by the HIP5600 in watts.
P = (VIN - VOUT)(IOUT)
Worst case θSA is calculated using the minimum TTS of
+127oC in Equation 6.
68
FIGURE 7. THERMAL CAPACITANCE MODEL OF HIP5600
Figure 7 shows the thermal capacitances of the TO-220
package, the integrated circuit and the heat sink, if used.
When power is initially applied, the mass of the package
absorbs heat which limits the rate of temperature rise of the
HIP5600
junction. With no heat sink CS equals zero and θSA equals the
difference between θJA and θJC. The following equations predict the transient junction temperature and the time to thermal
shutdown for ambient temperatures up to +85oC and power
levels up to 8W. The output current limit temperature coefficient (Figure 39) precludes continuous operation above 8W.
–t
T ≡
1
(EQ. 9)


--------
 1 – e τ1
Pθ

SA 


(EQ. 11B)
τ1 ≡ θ SA ( C P + C S )
Where:
τ ≡ θSA ( C P + C S )
t =
(EQ. 11A)
Where:
–t
-----

TJ ( t ) = TA + PθJC + PθSA  1 – e τ 

TJ ( t ) = TA + T1 + T2 + T3

–t
--------


T 2 ≡ 0.4Pθ JC  1 – e τ2
 P ( θ JC + θ SA ) + T A – T TS
– τln  -------------------------------------------------------------------
PθSA


(EQ. 10)
Where:
 ( 0.5C P + C S ) 0.5C P
τ2 ≡ 0.7θJC  ------------------------------------------------------------
CP + C S


For the TO-220, CP is 0.9Ws to 1.1Ws per degree compared
to about 2.6mWs per degree for the integrated circuit and C S
is 0.9Ws per degree per gram for aluminum heat sinks.
–t
Figure 8 shows the time to thermal shutdown versus power
dissipation for a part in +22oC still air and at various elevated
ambient temperatures with a θSA of +27oC/W from forced air
flow.
For the shorter shutdown times, the θSA value is not important but the thermal capacitances are. A more accurate
equation for the transient silicon surface temperature can be
derived from the model shown in Figure 7. Due to the distributed nature of the package thermal capacitance, the second
time constant is 1.7 times larger than expected.
10 2
(EQ. 11C)
T ≡
3

--------
0.6Pθ  1 – e τ3
JC


Where:
τ3 ≡ 0.6θ
(EQ. 11D)
C
JC D
Thermal Shutdown Hysteresis
Figure 9 shows the HIP5600 thermal hysteresis curve with
VIN = 100VDC , VOUT = 5V and IOUT = 10mA. Hysteresis is
added to the thermal shutdown circuit to prevent oscillations
as the junction temperature approaches the thermal shutdown limit. The thermal shutdown is reset when the input
voltage is removed, goes negative (i.e. AC operation) or
when the part cools down.
10 1
+22×oC
+70×oC
+85×oC
10 0
HEATING
8.0
IOUT (mA)
TIME TO THERMAL SHUTDOWN (s)
10
SHUTDOWN
REGION
6.0
4.0
COOLING
2.0
+100×oC
10-1
0.0
98.0
+115× oC
2.0
4.0
6.0
8.0
POWER DISSIPATION (W)
FIGURE 8. TIME TO THERMAL SHUTDOWN vs POWER
DISSIPATION
69
113.0
120
127
CASE TEMPERATURE (oC)
135
142
FIGURE 9. THERMAL HYSTERESIS CURVE
+120 o×C
10-2
0.0
105.0
10
AC to DC Operation
Since the HIP5600 has internal high voltage diodes in series
with its input, it can be connected directly to an AC power
line. This is an improvement over typical low current supplies
constructed from a high voltage diode and voltage dropping
resistor to bias a low voltage zener. The HIP5600 provides
better line and load regulation, better efficiency and heat
HIP5600
transfer. The latter because the TO-220 package permits
easy heat sinking.
The efficiency of either supply is approximately the DC
output voltage divided by the RMS input voltage. The
resistor value, in the typical low current supply, is chosen
such that for maximum load at minimum line voltage there is
some current flowing into the zener. This resistor value
results in excess power dissipation for lighter loads or higher
line voltages.
Using the circuit in Figure 3 with a 1000µF output capacitor
the HIP5600 only takes as much current from the power line
as the load requires. For light loads, the HIP5600 is even
more efficient due to it’s interaction with the output capacitor.
Immediately after the AC line goes positive, the HIP5600
tries to replace all the charge drained by the load during the
negative half cycle at a rate limited by the short circuit current limit (see “A1” and “B1” Figure 10). Since most of this
charge is replaced before the input voltage reaches its RMS
value, the power dissipation for this charge is lower than it
would be if the charge were transferred at a uniform rate during the cycle. When the product of the input voltage and current is averaged over a cycle, the average power is less than
if the input current were constant. Figure 11 shows the
HIP5600 efficiency as a function of load current for 80VRMS
and 132VRMS inputs for a 15.6V output.
Referring again to Figure 10, Curve “A1” shows the input
current for a 10mA output load and curve “B1” with a 3mA
output load. The input current spike just before the negative
going zero crossing occurs while the input voltage is less
than the minimum operating voltage but is so short it has no
detrimental effect. The input current also includes the charging current for the 0.02µF input decoupling capacitor C1.
The maximum load current cannot be greater than 1/2 of the
short circuit current because the HIP5600 only conducts over
1/2 of the line cycle. The short circuit current limit (Figure 38)
depends on the case temperature, which is a function of the
power dissipation. Figure 38 for a case temperature of
+100oC (i.e. no heat sink) indicates for AC operation the
maximum available output current is 10mA (1/2 x 20mA).
Operation from full wave rectified input will increase the
maximum output current to 20mA for the same +100oC case
temperature.
As a reminder, since the HIP5600 is off during the negative
half cycle, the output capacitor must be large enough to supply the maximum load current during this time with some
acceptable level of droop. Figure 10 also shows the output
ripple voltage, for both a 10mA and 3mA output loads “A2”
and “B2”, respectively.
Do’s And Don’ts
DC Operation
120VRMS, 60Hz
I IN
1. Do not exceed the absolute maximum ratings.
2. The HIP5600 requires a minimum output current of 1mA.
Minimum output current includes current through RF1.
Warning: If there is less than 1mA load current, the output voltage will rise. If the possibility of no load exists,
RF1 should be sized to sink 1mA under these conditions.
20mA/DIV.
A1
B1
V
REF 1.07V
RF1 MIN = ------------------ = ---------------- = 1kΩ
1mA
1mA
B2
VOUT
A2
3. Do not “HOT” switch the input voltage without protecting
the input voltage from exceeding ±650V. Note: inductance from supplies and wires along with the 0.02µF
decoupling capacitor can form an under damped tank circuit that could result in voltages which exceed the maximum ±650V input voltage rating. Switch arcing can
further aggravate the effects of the source inductance
creating an over voltage condition.
2ms/DIV.
100mV/DIV.
FIGURE 10. AC OPERATION
25
VIN = 80VRMS
23
Recommendation: Adequate protection means (such as
MOV, avalanche diode, surgector, etc.) may be needed
to clamp transients to within the ±650V input limit of the
HIP5600.
EFFICIENCY (%)
21
19
18
VIN = 132VRMS
16
14
12
10
VOUT = 15.6VDC
0.0
5.0
10.0
LOAD CURRENT (mA)
15.0
FIGURE 11. EFFICIENCY AS A FUNCTION OF LOAD CURRENT
70
4. Do not operate the part with the input voltage below the
minimum 50VDC recommended. Low voltage operation: For input voltages between 0V DC and +5VDC nothing happens (IOUT = 0), for input voltages between
+5V DC and +35V DC there is not enough voltage for the
pass transistor to operate properly and therefore a high
frequency (2MHz) oscillation occurs. For input voltages
+35VDC to +50VDC proper operation can occur with
some parts.
HIP5600
5. Warning: the output voltage will approach the input voltage if the adjust pin is disconnected, resulting in permanent damage to the low voltage output capacitor.
AC Operation
minimized by connecting the test equipment ground as
close to the circuit ground as possible.
CAUTION: Dangerous voltages may appear on exposed
metal surfaces of AC powered test equipment.
1. Do not exceed the absolute maximum ratings.
Application Circuits
+ 50VDC TO 400VDC BUS
HIP5600
0.5m A
C1
0.02µF
±
VIN
0.5mA
ADJ
V
REF
1.07V
RF1 MIN = ------------------ = ------------------ = 2kΩ
VOUT
2. The HIP5600 requires a minimum output current of
0.5mA. Minimum output current includes current through
RF1. Warning: If there is less than 0.5mA output current,
the output voltage will rise. If the possibility of no load
exists, RF1 should be sized to sink 0.5mA under these
conditions.
+ VOUT
3. If using a laboratory AC source (such as VARIACs or
step-up transformers, etc.) be aware that they contain
large inductances that can generate damaging high voltage transients when they are switched on or off.
RF1
C3
10µF
Recommendations
C2
10µF
RF2
(1) Preset VARIAC output voltage before applying power
to part.
(2) Adequate protection means (such as MOV, avalanche diode, surgector, etc.) may be needed to clamp
transients to within the ±650V input limit of the HIP5600.
4. Do not operate the part with the input voltage below the
minimum 50VRMS recommended. Low voltage operation similar to DC operation (reference step 4 under
DC operation).
5. Warning: the output voltage will approach the input voltage if the adjust pin is disconnected, resulting in permanent damage to the low voltage output capacitor.
FIGURE 12. DC/DC CONVERTER
The HIP5600 can be configured in most common DC linear
regulator applications circuits with an input voltage between
50VDC to 400VDC (above the output voltage) see Figure 12.
A 10µF capacitor (C2) provides stabilization of the output
stage. Heat sinking may be required depending upon the
power dissipation. Normally, choose RF1 << VREF / IADJ.
(NOTE 1)
1kΩ
General Precautions
HIP5600
Recommendations for Evaluation of the HIP5600
in the Lab
a) The use of battery powered DVMs and scopes will eliminate ground loops.
b) When connecting test equipment, locate grounds as
close to circuit ground as possible.
c) Input current measurements should be made with a noncontact current probe.
If AC powered test equipment is used, then the use of an
isolated plug is recommended. The isolated plug eliminates
any voltage difference between earth ground and AC
ground. However, even though the earth ground is disconnected, ground loop currents can still flow through transformer of the test equipment. Ground loops can be
71
C1
0.02µF
VIN
ADJ
Background: Input to output parasitic impedances exist in
most test equipment power supplies. The inter-winding
capacitance of the transformer may result in substantial current flow (mA) from the equipment power lines to the DC
ground of the HIP5600. This “ground loop” current can result
in erroneous measurements of the circuits performance and
in some cases lead to overstress of the HIP5600.
VOUT
Instrumentation Effects
+ VOUT
RF1
C3
10µF
C2
10µF
SURGE
PROTECTION
NOTE 1. 200VRMS - 280VRMS
Operation Only
RF2
FIGURE 13. AC/DC CONVERTER
The HIP5600 can operate from an AC voltage between
50V RMS to 280VRMS, see Figure 13. The combination of a
1kΩ (2W) input resistor and a V275LA10B MOV provides
input surge protection up to 6kV 1.2 x 50µs oscillating and
pulse waveforms as defined in IEEE/ANSI C62.41.1980.
When operating from 120VAC , a V130LA10B MOV provides
protection without the 1kΩ resistor.
The output capacitor is larger for operation from AC than DC
because the HIP5600 only conducts current during the positive half cycle of the AC line. The efficiency is approximately
equal to V OUT /V IN (RMS), see Figure 11.
HIP5600
The HIP5600 provides an efficient and economical solution
as a start-up supply for applications operating from either AC
(50VRMS to 280VRMS) or DC (50VDC to 400V DC).
+ 50VDC TO 400VDC
BUS
VIN
ADJ
VOUT
HIP5600
RF1
10µF
part, the amount of heat sinking (if any) and the ambient temperature. For example; at 400VDC with no heat sink, it will
provide 20mA for about 8s, see Figure 8.
Power supply efficiency is improved by turning off the
HIP5600 when the SMPS is up and running. In this application
the output of the HIP5600 would be set via RF1 and RF2 to be
about 9V. The tickler winding would be adjusted to about 12V
to insure that the HIP5600 is kept off during normal operating
conditions.The input current under these conditions is approximately equal to IBIAS. (See Figure 27).
±
The HIP5600 can supply a 450µA (±20%) constant current.
(See Figure 15). It makes use of the internal bias network.
See Figure 27 for bias current versus input voltage.
+12V
With the addition of a potentiometer and a 10µF capacitor the
HIP5600 will provide a constant current source. IOUT is given
by Equation 13 in Figure 16.
RF2
VOUT
PWM
FIGURE 14. START UP CIRCUIT
The HIP5600 has on chip thermal protection and output current limiting circuitry. These features eliminate the need for
an in-line fuse and a large heat sink.
The HIP5600 can provide up to 40mA for short periods of time
to enable start up of a switch mode power supply‘s control circuit. The length of time that the HIP5600 will be on, prior to
thermal shutdown, is a function of the power dissipation in the
The HIP5600 can control a P-channel MOSFET or IGPT in a
self-oscillating buck regulator. The circuit shown (Figure 17)
shows the self-oscillating concept with a P-IGBT driving a
dedicated fan load. The output voltage is set by the resistor
combination of RF1, RF2, and RF3. Components C3 and
RF3 impresses the output ripple voltage across RF1 causing
the HIP5600 to oscillate and control the conduction of the
P-IGBT. The start-up protection components limit the initial
surge current in the P-IGBT by forcing this device into its
active region. The snubber circuit is recommended to reduce
the power dissipation of the P-IGBT.
+50VDC TO +400VDC
HIP5600
0.02µF
+20VDC TO +400VDC
R1
IOUT
NOTES:
LOAD
1. V OUT Floating
2. Fixed 500µA Current Source
IOUT
±
FIGURE 15. CONSTANT 450µA CURRENT SOURCE
72
±
VIN
ADJ
VOUT
VIN
VOUT
ADJ
HIP5600
IOUT = 1.21V
R1
(EQ. 13)
10µF
FIGURE 16. ADJUSTABLE CURRENT SOURCE
HIP5600
START-UP PROTECTION
P-IGBT
HIP5600
VIN
ADJ
VOUT
SNUBBER CIRCUIT
RF1
+
RF2
C3
-
DC
FAN
RF3
FIGURE 17. HIGH CURRENT “BUCK” REGULATOR CONCEPT
-0.8
-1.0
1mA TO 20mA
-1.2
-1.4
-1.6
1mA TO 30mA
-40
-20
VIN = 50VDC
0
25
40
60
CASE TEMPERATURE (oC)
80
100
-1
-2
1mA TO 10mA
-3
-4
-5
-6
1mA TO 20mA
-7
-8
1mA TO 30mA
VIN = 400VDC
-9
-10
-40
-20
0
25
40
CASE TEMPERATURE (oC)
60
80
FIGURE 18. LOAD REGULATION vs TEMPERATURE
FIGURE 19. LOAD REGULATION VS. TEMPERATURE
85
90
VIN = 400VDC, IL = 10mA, f = 120Hz, T C = +25oC
VIN = 170VDC, IL = 10mA, f = 120Hz, TC = +25 oC
80
RIPPLE REJECTION (dB)
1mA TO 10mA
-0.6
OUTPUT VOLTAGE DEVIATION (%)
-0.4
80
75
70
1µF BYPASS CAPACITOR
10µF BYPASS CAPACITOR
65
60
55
NO BYPASS CAPACITOR
50
45
0
10
20
30
40 50 60 70 80
OUTPUT VOLTAGE (V)
90
100 110
FIGURE 20. RIPPLE REJECTION RATIO (OUTPUT VOLTAGE)
73
RIPPLE REJECTION (dB)
OUTPUT VOLTAGE DEVIATION (%)
Typical Performance Curves
70
1µF BYPASS CAPACITOR
10µF BYPASS CAPACITOR
60
50
NO BYPASS CAPACITOR
40
30
0
50
100
150
200
250
OUTPUT VOLTAGE (V)
300
350
FIGURE 21. RIPPLE REJECTION RATIO (OUTPUT VOLTAGE)
HIP5600
Typical Performance Curves
85
85
VIN = 170VDC, IL = 10mA, VOUT = 15V, TC = +25oC
80
75
70
65
60
55
1µF BYPASS CAPACITOR
50
45
10
70
65
60
55
1µF BYPASS CAPACITOR
1M
45
10M
1
10
RIPPLE REJECTION (dB)
75
70
1µF BYPASS CAPACITOR
10µF BYPASS CAPACITOR
60
55
NO BYPASS CAPACITOR
0
5
10k
100k
1M
10M
VIN = 400VDC, VOUT = 10mA, f = 120Hz, TC = +25oC
80
(REFERENCE FIGURE 3)
65
1k
FIGURE 23. RIPPLE REJECTION RATIO (INPUT FREQUENCY)
VIN = 170VDC, VOUT = 10mA, f = 120Hz, TC = +25oC
80
100
INPUT FREQUENCY (Hz)
85
85
RIPPLE REJECTION (dB)
75
NO BYPASS CAPACITOR
100
1k
10k
100k
INPUT FREQUENCY (Hz)
FIGURE 22. RIPPLE REJECTION RATIO (INPUT FREQUENCY)
50
10µF BYPASS
CAPACITOR
50
NO BYPASS CAPACITOR
1
VIN = 400VDC , IL = 10mA, VOUT = 15V, TC = +25 oC
80
10µF BYPASS
CAPACITOR
RIPPLE REJECTION (dB)
RIPPLE REJECTION (dB)
(Continued)
(REFERENCE FIGURE 3)
75
70
1µF BYPASS CAPACITOR
65
10µF BYPASS CAPACITOR
60
NO BYPASS CAPACITOR
55
10
15
20
25
OUTPUT CURRENT (mA)
30
50
35
FIGURE 24. RIPPLE REJECTION RATIO (OUTPUT CURRENT)
0
5
10
15
20
25
OUTPUT CURRENT (mA)
30
35
FIGURE 25. RIPPLE REJECTION RATIO (OUTPUT CURRENT)
520
IOUT = 0
510
500
C2 = 0.01µF, C3 = 0µF
TC = +100oC
490
IBIAS (µA)
OUTPUT IMPEDANCE (Ω)
100
10.0
C2 = 10µF, C3 = 0µF
480
TC = -40oC
470
460
TC = +25 oC
450
1.0
440
C2 = 10µF, C3 = 10µF
430
0.1
10
100
1K
10K
FREQUENCY (Hz)
100K
FIGURE 26. OUTPUT IMPEDANCE
74
1M
420
50
100
200
300
INPUT VOLTAGE (VDC)
FIGURE 27. IBIAS vs INPUT VOLTAGE
400
HIP5600
Typical Performance Curves
(Continued)
100mV/DIV
C3 = 10µF
VOUT
20mV/DIV
15V
VOUT
C3 = 10µF
C3 = 0µF
15V
400V
VOUT = 15VDC
IL= 5mA
TJ = +25oC
100V
OUTPUT CURRENT
100V/DIV
INPUT
VOLTAGE
T = 100ms/DIV
0V
C3 = 0µF
FIGURE 29. LOAD TRANSIENT RESPONSE
VIN = 400VDC
1mA
REFERENCE VOLTAGE (V)
REFERENCE VOLTAGE (V)
1.25
VIN = 50VDC
1.18
5mA
1.17
1.16
10mA
1.15
1.14
30mA
1.13
1.12
20mA
1.11
-40
-20
0
25
40
60
CASE TEMPERATURE (oC)
80
1mA
1.20
5mA
1.15
10mA
1.10
20mA
1.05
1.00
100
30mA
-40
-20
0
25
40
60
80
CASE TEMPERATURE (oC)
FIGURE 30. REFERENCE VOLTAGE vs TEMPERATURE
FIGURE 31. REFERENCE VOLTAGE vs TEMPERATURE
1.20
1.20
1.19
IOUT = 10mA
1.18
1.17
TC = -40oC
REFERENCE VOLTAGE (V)
REFERENCE VOLTAGE (V)
1.10
T= 100ms/DIV
0mA
1.21
1.19
VIN = 400VDC
VOUT = 15V
TJ = +25 oC
5mA
FIGURE 28. LINE TRANSIENT RESPONSE
1.20
5mA/DIV
10mA
1.16
1.15
1.14
TC = +25o C
1.13
1.12
1.11
1.10
TC = +100oC
1.09
1.08
0
100
200
300
INPUT VOLTAGE (VDC)
400
FIGURE 32. REFERENCE VOLTAGE vs INPUT VOLTAGE
75
1.18
1mA
1.16
5mA
1.14
10mA
1.12
1.10
20mA
1.08
30mA
1.06
1.04
0
100
200
300
INPUT VOLTAGE (VDC)
400
FIGURE 33. REFERENCE VOLTAGE vs VIN; CASE TEMPERATURE OF +25oC
HIP5600
Typical Performance Curves
(Continued)
80
80
VIN = 400VDC
VIN = 50VDC
75
75
ADJ CURRENT (µA)
ADJ CURRENT (µA)
1mA
70
20mA
65
60
30mA
55
10mA
5mA
65
1mA
60
20mA
55
30mA
50
50
45
70
45
-40
-20
0
25
40
60
CASE TEMPERATURE (oC)
80
-40
100
-20
FIGURE 34. IADJ vs TEMPERATURE
0
25
40
CASE TEMPERATURE (oC)
2000
VIN = 100VDC
TC = 25oC
TC = +25oC
1500
CURRENT (µA)
765
760
TC = +100oC
755
MINIMUM LOAD
CURRENT
1000
BIAS CURRENT
IIN
500
IOUT
750
100
200
300
0
400
IADJ
1
2
INPUT VOLTAGE (VDC)
FIGURE 36. MINIMUM LOAD CURRENT vs V IN
3
VOUT - VADJ (VDC)
50
TC = -40 oC
45
40
TC = +25oC
35
30
TC = +100oC
25
20
50
100
150
200
250
300
350
INPUT-OUTPUT (VDC)
FIGURE 38. CURRENT LIMIT vs TEMPERATURE
76
4
FIGURE 37. TERMINAL CURRENTS vs FORCED VREF
55
OUTPUT CURRENT (mA)
LOAD CURRENT (µA)
770
50
80
FIGURE 35. IADJ vs TEMPERATURE
775
745
60
400
5
HIP5600
Evaluation Boards
θSA = 22oC/W
HEAT SINK
VIN
ADJ
F1
3.25”
3.25”
HIP5600
VOUT
RF1
RS
VIN
+
C2
MOV
C1 RF2 C3
VOUT
HIP5600 EVALUATION BOARD
3.25”
3.25”
FIGURE 39. EVALUATION BOARD (TOP)
FIGURE 40. EVALUATION BOARD METAL MASK (BOTTOM)
3.25”
HEAT SINK
ADJ
VIN
VOUT
+
-
VIN
VOUT
HIP5600 EVALUATION BOARD
3.25”
FIGURE 41. EVALUATION BOARD METAL MASK (TOP)
77
HIP5600
Single-In-Line Plastic Packages (SIP)
ØP
Z3.1B
A
E
F
3 LEAD PLASTIC SINGLE-IN-LINE PACKAGE
INCHES
Q
H1
D
L1
b1
L
b
1
2
c1
3
e
e1
J1
NOTES:
1. Lead dimension and finish uncontrolled in zone L1.
2. Position of lead to be measured 0.250 inches (6.35mm) from bottom of dimension D.
3. Position of lead to be measured 0.100 inches (2.54mm) from bottom of dimension D.
4. Controlling dimension: INCH.
78
MILLIMETERS
SYMBOL
MIN
MAX
MIN
MAX
NOTES
A
0.140
0.190
3.56
4.82
-
b
0.015
0.040
0.38
1.02
-
b1
0.045
0.070
1.14
1.77
1
c1
0.014
0.022
0.36
0.56
1
D
0.560
0.650
14.23
16.51
-
E
0.380
0.420
9.66
10.66
-
e
0.090
0.110
2.29
2.79
2
e1
0.190
0.210
4.83
5.33
2
F
0.020
0.055
0.51
1.39
-
H1
0.230
0.270
5.85
6.85
-
J1
0.080
0.115
2.04
2.92
3
L
0.500
0.580
12.70
14.73
-
L1
-
0.250
6.35
1
-
ØP
0.139
0.161
3.53
4.08
-
Q
0.100
0.135
2.54
3.43
Rev. 1 2/95