SIPEX SP6831EK/TR

®
SP6830/6831
Low Power Voltage Inverters With Shutdown
FEATURES
■ 99.9% Voltage Conversion Efficiency
■ +1.15V to +5.3V Input Voltage Range
■ Inverts Input Supply Voltage
■ 70µA Supply Current for the SP6830
■ 200µA Supply Current for the SP6831
■ 35kHz Operating Frequency for the
SP6830
■ 120kHz Operating Frequency for the
SP6831
■ <1µA Shutdown Current
■ 6-pin SOT23-6 Package
■ Ideal for +3.6V Lithium Ion Battery
Applications
■ Reverse +3.6V Lithium Ion Battery
Protection
■ 25mA Output Current
■ 19Ω Output Resistance
APPLICATIONS
■ Small LCD Negative Bias Voltage
■ Power Amplifier Negative Bias Voltage
■ +5V to -5V Voltage Conversion
DESCRIPTION
The SP6830/6831 devices are CMOS Charge Pump Voltage Inverters that can be implemented into designs which require a negative voltage from a battery voltage source as low as
+1.15V or a power supply rail voltage as high as +5.3V. The SP6830/6831 devices are ideal
for both battery-powered and board level voltage conversion applications with a typical
operating current of 70µA for the SP6830 and 200µA for the SP6831. These devices combine
an ultra-low shutdown current of <1µA with high efficiency (>95% over most of its load-current
range) which are ideal for designs using batteries such as cell phones, PDAs, medical
instruments, and other portable equipment. The SP6830/6831 devices are available in a
space-saving 6-pin SOT23-6 Package.
6 C1+
VOUT 1
VIN 2
C1-
Rev. 9-22-00
3
SP6830
SP6831
5 SHDN
4 GND
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
ABSOLUTE MAXIMUM RATINGS
These are stress ratings only and functional operation
of the device at these ratings or any other above those
indicated in the operation sections of the specifications
below is not implied. Exposure to absolute maximum
rating conditions for extended periods of time may
affect reliability.
VIN.........................................................-0.3V to +5.6V
VOUT......................................................-5.6V to +0.3V
IOUT......................................................................50mA
Storage Temperature.......................-65OC to +150OC
Lead Temperature (Soldering)..........................300OC
Power Dissipation Per Package
6-pin SOT (derate 4.35mW/OC above +70OC)............400mW
SPECIFICATIONS
VIN = +5V, C1=C2=C3=3.3µF for the SP6830, C1=C2=C3=1µF for the SP6831, and TAMB=-40°C to +85°C unless otherwise noted. Typical values are
taken specifically at TAMB=+25°C.
PARAMETER
MIN.
MAX.
UNITS
5.3
V
RL = 1kΩ
150
400
µA
SP6830
SP6831
1.8
V
RL = 1kΩ, NOTE1
VIN
0.5
V
VIN = VMIN to VMAX
VIN = VMIN to VMAX
0.1
1.0
µA
SHDN = GND, VIN = 5V, NOTE 2
35
120
56.3
200
kHz
SP6830
SP6831
19
45
Ω
IOUT = 5mA to 25mA, NOTE 3
99.9
%
RL = open
Power Efficiency (Ideal)
98
%
RL = 1kΩ, NOTE 4
Power Efficiency (Actual)
96
%
RL = 1kΩ, NOTE 5
Supply Voltage Range, VDD
TYP.
1.15
Supply Current, IVIN
70
200
Guaranteed Start-up Voltage
Shutdown Input Voltage
HIGH
LOW
1.5
Shutdown Supply Current
Oscillator Frequency, fOSC
24.5
70
Output Resistance
Voltage Conversion Efficiency
95
CONDITIONS
Note 1: Minimum VIN required for VO = -VIN +0.2V.
Note 2: During the shutdown mode, VIN is disconnected from VOUT.
Note 3: Capacitors are approximately 20% of the output impedance where ESR =
Note 4: Power Efficiency (Ideal) =
Note 5: Power Efficiency (Actual) =
Rev. 9-22-00
1
fOSC x C
.
VOUT x IOUT
-VIN x (-VIN/RL)
VOUT x IOUT
VIN x IIN
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
PINOUT
PIN ASSIGNMENTS
Pin 1— VOUT — Inverting charge pump output.
VIN 2
C1-
3
Pin 2 — VIN — Input to the positive power
supply.
6 C1+
VOUT 1
SP6830
SP6831
5 SHDN
Pin 3 — C1- — Negative terminal to the charge
pump capacitor.
4 GND
Pin 4 — GND — Ground reference.
Pin 5 — SHDN — Active LOW Shutdown
input.
Pin 6 — C1+ — Positive terminal to the charge
pump capacitor.
2
VIN
VIN
4-Phase
Clock
SD
C3
ON
5 SHDN
OFF
SP6830
SP6831
Shutdown
C1+
6
C1VOUT
3
1
C1
4 GND
Comparator
VOUT
VEE*
Pump
Switches
SD
*VEE = the lower voltage of VOUT and GND
DEVICE C1
SP6830 3.3µF
SP6831 1µF
C2
3.3µF
1µF
C3
3.3µF
1µF
VOUT
C2
RL
fOSC
35kHz
120kHz
Figure 1. Voltage Inverter Circuit for the SP6830/6831
Rev. 9-22-00
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
TYPICAL PERFORMANCE CHARACTERISTICS
40
30
35
25
Output Resistance(Ohms)
Output Resistance(Ohms)
VIN = +5.0V, C1 = C2 = C3 = 3.3µF for SP6830, C1 = C2 = C3 = 1µF for SP6831, and TAMB = 25OC unless otherwise
noted. The SP6830/6831 devices use the circuit found in Figure 17 when obtaining the following typical
performance characteristics (unless otherwise noted).
30
25
20
15
10
5
20
15
10
0
2
2.5
3
3.5
4
4.5
5
5
0
-40
5.5
-15
Supply Voltage(V)
35
60
85
Temperature(C)
Figure 3. Output Resistance vs. Temperature
Figure 2. Output Resistance vs. Supply Voltage
50
175
150
40
125
Frequency (kHz)
Frequency(kHz)
10
30
20
10
100
75
50
25
0
0
2
2.5
3
3.5
4
4.5
5
5.5
2
2.5
Supply Voltage(V)
3.5
4
4.5
5
5.5
Supply Voltage(V)
Figure 5. Charge Pump Frequency vs. Supply Voltage
for the SP6831
Figure 4. Charge Pump Frequency vs. Supply Voltage
for the SP6830
Rev. 9-22-00
3
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN = +5.0V, C1 = C2 = C3 = 3.3µF for SP6830, C1 = C2 = C3 = 1µF for SP6831, and TAMB = 25OC unless otherwise
noted. The SP6830/6831 devices use the circuit found in Figure 17 when obtaining the following typical
performance characteristics (unless otherwise noted).
50
175
150
Frequency (kHz)
Frequency (kHz)
40
30
20
10
125
100
75
50
25
0
-40
-15
10
35
60
0
-40
85
Temperature(C)
-15
10
35
60
85
Temperature(C)
Figure 7. Charge Pump Freqency vs. Temperature for
the SP6831
Figure 6. Charge Pump Freqency vs. Temperature for
the SP6830
125
300
250
Supply Current (µA)
Supply Current (mA)
100
75
50
25
200
150
100
50
0
0
2
2.5
3
3.5
4
4.5
5
5.5
2
2.5
Supply Voltage(V)
3.5
4
4.5
5
5.5
Figure 9. Supply Current vs. Supply Voltage for the
SP6831
Figure 8. Supply Current vs. Supply Voltage for the
SP6830
Rev. 9-22-00
3
Supply Voltage(V)
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN = +5.0V, C1 = C2 = C3 = 3.3µF for SP6830, C1 = C2 = C3 = 1µF for SP6831, and TAMB = 25OC unless otherwise
noted. The SP6830/6831 devices use the circuit found in when obtaining the following typical performance
characteristics (unless otherwise noted).
250
500
450
200
Output Ripple (mVP-P)
Output Ripple (mVP-P)
400
350
150
300
250
VIN = 5V, Vout = -4V
100
200
150
VIN = 3.3V, VOUT = -2.5V
100
VIN = 2V, VOUT = -1.5V
VIN = 5V, VOUT = -4V
VIN = 3.3V, VOUT = -2.5V
50
VIN= 2V, VOUT= -1.5V
50
0
0
0
10
20
30
40
0
10
Capacitance (uF)
30
40
Capacitance (uF)
Figure 10. Output Voltage Ripple vs. Capacitance for
the SP6830
Figure 11. Output Voltage Ripple vs. Capacitance for
the SP6831
70
70
VIN= 5V, VOUT = -4V
VIN = 5V, VOUT= -4V
60
50
VIN= 3.3V, VOUT = -2.5V
40
30
20
VIN= 5V, VOUT = -4V
60
Output Current (mA)
Output Current (mA)
20
ViN= 2V, VOUT = -1.5V
50
VIN = 3.3V, VOUT = -2.5V
40
30
ViN= 2V, VOUT = -1.5V
20
10
10
0
0
0
0
10
20
30
Capacitance (uF)
20
30
40
Capacitance (uF)
Figure 13. Output Current vs. Supply Voltage for the
SP6831
Figure 12. Output Current vs. Capacitance for the
SP6830
Rev. 9-22-00
10
40
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN = +5.0V, C1 = C2 = C3 = 3.3µF for SP6830, C1 = C2 = C3 = 1µF for SP6831, and TAMB = 25OC unless otherwise
noted. The SP6830/6831 devices use the circuit found in when obtaining the following typical performance
characteristics (unless otherwise noted).
Power Efficiency (%)
100
95
VIN = 3.3V
90
ILOAD = 5mA
VOUT = -3.2
85
80
75
0
5
10
15
20
25
Output Current(mA)
Figure 14. Power Efficiency vs. Output Current
Figure 15. Output Noise and Ripple for the SP6830
VIN = 3.3V
ILOAD = 5mA
VOUT = -3.2V
Figure 16. Output Noise and Ripple for the SP6831
Rev. 9-22-00
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
VOUT
1
2 SP6830 5
C1SP6831
3
4
VIN
C2
6
RL
C1+
SHDN
GND
C3
C1
Figure 17: SP6830/6831 Connected as a Voltage Inverter in its Typical Operating Circuit; this Circuit Was Used to
Obtain the Typical Performance Characteristics Found in Figures 2 Through 16 (unless otherwise noted)
Rev. 9-22-00
SP6830/6831 Low Power Voltage Inverters With Shutdown
8
© Copyright 2000 Sipex Corporation
DESCRIPTION
The SP6830/6831 devices are CMOS Charge
Pump Voltage Converters that can be used to
invert a +1.15V to +5.3V input voltage. These
devices are ideal for designs involving batterypowered and/or board level voltage conversion
applications.
VOUT = -VIN
VIN
The typical operating frequency of the SP6830
is 35kHz. The typical operating frequency of
the SP6831 is 120kHz. The SP6830 has a
typical operating current of 70µA and the SP6831
operates at 200µA. Both devices can output
25mA with a voltage drop of 500mV. The
devices are ideal for LCD panel bias applications,
cellular phones, pagers, PDAs, medical
instruments, and other portable battery-powered
equipment. The SP6830/6831 devices combine
a high efficiency (>95% over most of its loadcurrent range) with a low quiescent current.
C1
S3
S2
C2
S4
VOUT
Figure 18. Circuit for an Ideal Voltage Inverter
Charge-Pump Output
The output of the SP6830/6831 devices is not
regulated and therefore is dependent on the
output resistance and the amount of load current.
As the load current increases, losses may slightly
increase at the output and the voltage may become
slightly more positive. The loss at the negative
output, VLOSS, equals the current draw, IOUT, from
VOUT times the negative converter's source
resistance, RS:
THEORY OF OPERATION
The SP6830/6831 devices should theoretically
produce an inverted input voltage. In real world
applications, there are small voltage drops at the
output that reduce efficiency. The circuit of an
ideal voltage inverter can be found in Figure 18.
The voltage inverters require two external
capacitors to store the charge. A description of
the two phases follows:
VLOSS = IOUT x RS.
Phase 1
In the first phase of the clock cycle, switches S2
and S4 are opened and S1 and S3 closed. This
connects the flying capacitor, C1, from VIN to
ground. C1 charges up to the input voltage
applied at VIN.
The actual inverted output voltage at VOUT will
equal the inverted voltage difference of VIN and
VLOSS:
VOUT = -(VIN - VLOSS).
Phase 2
In the second phase of the clock cycle, switches
S1 and S3 are opened and S2 and S4 are closed.
This connects the flying capacitor, C1, in parallel
with the output capacitor, C2. The charge stored
in C1 is now transferred to C2. Simultaneously,
the negative side of C2 is connected to VOUT and
the positive side is connected to ground. With
the voltage across C2 smaller than the voltage
across C1, the charge flows from C1 to C2 until
the voltage at the VOUT equals -VIN.
Rev. 9-22-00
S1
Efficiency
Theoretically, the total power loss of a switched
capacitor voltage converter can be summed up as
follows:
∑PLOSS = PINT + PCAP + PCONV,
where PLOSS is the total power loss, PINT is the total
internal loss in the IC including any losses in the
MOSFET switches, PCAP is the resistive loss of
the charge pump capacitors, and PCONV is the total
SP6830/6831 Low Power Voltage Inverters With Shutdown
9
© Copyright 2000 Sipex Corporation
conversion loss during charge transfer between
the flying and output capacitors. These are the
three theoretical factors that may effect the power
efficiency of the SP6830/6831 devices in designs.
where
POUT = VOUT x IOUT
and
Any internal losses come from the IC's on board
circuitry. Losses in the IC can be induced by the
input voltage, the frequency of the oscillator, and
the ambient temperature. The most influential
internal loss in the IC may be found in the poweron resistance of the internal MOSFET switches.
PIN = VIN x IIN
where POUT is the power output, VOUT is the
output voltage, IOUT is the output current, PIN is
the power from the supply driving the SP6830/
6831 devices, VIN is the supply input voltage, and
IIN is the supply input current.
Any of the losses with the charge pump capacitors
will be induced by the capacitor's ESR. The
affects of the ESR losses and the output resistance
can be found in the following equation:
Ideal Efficiency
The ideal efficiency is not the true power
efficiency because it does not involve the input
power which includes the input current losses in
the charge pump. The ideal efficiency can be
determined with the following equation:
IOUT2 x ROUT = PCAP + PCONV
and
ROUT ≈ 4 x (2 x RSWITCHES + ESRC1) +
1
ESRC2 + fOSC x C1 ,
Efficiency (ideal) =
POUT
x 100% ,
POUT(IDEAL)
where
where IOUT it the output current, ROUT is the
circuit's output resistance, RSWITCHES is the internal
resistance of the MOSFET switches, ESRC1 and
ESRC2 are the ESR of their respective capacitors,
and fOSC is the oscillator frequency. This term
with fOSC is derived from an ideal switchedcapacitor circuit as seen in Figure 19.
POUT(IDEAL) = -VIN x -VIN ,
RL
f
VOUT
V+
Any losses due to the conversion process will
happen during the charge transfer between the
flying capacitor, C1, and the output capacitor,
C2, when there is a voltage difference between
them. PCONV can be determined by the following
equation:
C1
C2
RL
PCONV = fOSC x [ 1/2 x C1 x (VIN2 - VOUT2) +
1
/2 x C2 x (VRIPPLE2 - 2VOUTVRIPPLE) ].
Requivalent
VOUT
V+
Actual Efficiency
To determine the actual efficiency of the SP6830/
6831 device operation, a designer can use the
following equation:
Requivalent =
Efficiency (actual) = POUT x 100% ,
PIN
Rev. 9-22-00
1
f x C1
C2
RL
Figure 19. Equivalent Circuit for an Ideal Switched
Capacitor
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
Flying Capacitor
Decreasing flying capacitor, C1, values will
increase the output resistance of the SP6830/
6831 devices while increasing C1 will reduce the
output resistance. There is a point where
increasing C1 will have a negligible effect on the
output resistance due to the the domination of the
output resistance by the internal MOSFET switch
resistance and the total capacitor ESR.
and POUT is the the power output. Both efficiencies
are provided to designers for comparison.
APPLICATION INFORMATION
For the following applications, C1 = C2 = C3 =
3.3µF for the SP6830 and C1 = C2 = C3 = 1.0µF
for the SP6831.
Capacitor Selection
Low ESR capacitors are needed to obtain low
output resistance. Refer to Table 1 for some
suggested low ESR capacitors. The output
resistance of the SP6830/6831 devices is a
function of the ESR of C1 and C2. This output
resistance can be determined by the equation
previously provided in the Efficiency section:
Output Capacitor
Increasing output capacitor, C2, values will
decrease the output ripple voltage. Reducing the
ESR of C2 will reduce both output ripple voltage
and output resistance. If higher output ripple can
be tolerated in designs, smaller capacitance values
for C2 should be used with light loads. The
following equation can be used to calculate the
peak-to-peak ripple voltage:
ROUT ≈ 4 x (2 x RSWITCHES + ESRC1) +
1
ESRC2 + fOSC x C1 ,
VRIPPLE = 2 x IOUT x ESRC2 +
where ROUT is the circuit's output resistance,
RSWITCHES is the internal resistance of the MOSFET
switches, ESRC1 and ESRC2 are the ESR of their
respective capacitors, and fOSC is the oscillator
frequency. This term with fOSC is derived from an
ideal switched-capacitor circuit as seen in Figure
19.
IOUT
fOSC x C2 .
Input Bypass Capacitor
The bypass capacitor at the input voltage will
reduce AC impedance and the impact of any of
the SP6830/6831 device's switching noise. It is
recommended that for heavy loads a bypass
capacitor approximately equal to the flying
capacitor, C1, be used. For light loads, the value
of the bypass capacitor can be reduced.
Minimizing the ESR of C1 and C2 will minimize
the total output resistance and will improve the
efficiency.
SIPEX PART
NUMBER
MANUFACTURER/
TELEPHONE #
PART NUMBER
CAPACITANCE /
VOLTAGE
MAX ESR
@ 100kHz
CAPACITOR
SIZE/TYPE
SP6830
KEMET /
864-963-6300
T494B335*020
3.3µF / 20V
1.5Ω
Case B /
Tantalum
SP6830
SPRAGUE /
207-324-4140
595D335X0035
3.3µF / 35V
2.0Ω
Case C /
Tantalum
SP6830
TDK /
847-803-6100
C3216X5R1A335K
3.3µF / 10V
0.04Ω
1206 / X5R
SP6831
AVX /
843-448-9411
0805ZC105K
1µF / 10V
0.04Ω
0805 / X7R
SP6831
KEMET/
864-963-6300
C0805C105KRAC
1µF / 10V
0.05Ω
0805 / X7R
SP6831
TDK /
847-803-6100
C2012X5R1A105K
1µF / 10V
0.05Ω
0805 / X5R
Table 1. Suggested Low ESR Surface Mount Capacitors
Rev. 9-22-00
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
+VIN
IN
C1
GND
6
SP6830
SP6831
C1+
C1
4
GND
6
1
3
C1+
C1
“2”
OUT
C1-
SHDN 5
2
SP6830
SP6831
4
“1”
C1-
IN
IN
2
2
C1+
1
3
GND
6
4
“n”
OUT
C1-
SHDN 5
RTOT
SP6830
SP6831
1
3
OUT
VOUT
SHDN 5
Shutdown
Control
Input
VOUT = -VIN
RTOT = ROUT where VOUT = output voltage,
n
VIN = input voltage,
RTOT = total resistance of the devices connected in parallel,
ROUT = the output resistance of a single device, and
n = the total number of devices connected in parallel.
C2 x n
Figure 20. SP6830/6831 Devices Connected in Parallel to Reduce Total Output Resistance
+VIN
IN
IN
C1
GND
C1-
6
4
SP6830
SP6831
C1+
SHDN
5
5
C1
“1”
3
1
IN
2
2
C1+
OUT
GND
C1-
SP6830
SP6831
2
SHDN
C1+
5
C1
4
“2”
1
3
OUT
C2
C2
GND
C1-
3
SP6830
SP6831
SHDN
5
4
“n”
5
1
OUT
VOUT
C2
VOUT = -n x VIN
where VOUT = output voltage,
VIN = input voltage, and
n = the total number of cascaded devices connected.
Figure 21. SP6830/6831 Devices Cascaded to Increase Output Voltage
Rev. 9-22-00
SP6830/6831 Low Power Voltage Inverters With Shutdown
12
© Copyright 2000 Sipex Corporation
When loading the SP6830/6831 devices from IN
to OUT, the input current remains constant
(disregarding any spikes due to internal
switching). Implementing a 0.1µF bypass
capacitor should be sufficient.
When loading the SP6830/6831 devices from
OUT to GND, the current from the supply will
switch from twice that of IOUT and zero amperes.
Designers should implement a large bypass
capacitor (C3 = C1) if the supply has a high AC
impedance.
GND
4
SP6830
SP6831
1
Voltage Inverter
A designer can find the most common application
for the SP6830/6831 devices in Figure 17 as a
voltage inverter. The only external components
needed are 3 capacitors: the flying capacitor, C1,
the output capacitor, C2, and the bypass capacitor,
C3 (if necessary). This circuit is used to obtain
the Typical Performance Characteristics found
in Figures 2 to 16 (unless otherwise noted).
1N5817
Figure 22. Protection for Heavy Loads
Combining a Doubler and Inverter Circuit
A designer can connect a SP6830/6831 device in
a combination doubler/inverter circuit as seen in
Figure 23. The doubler uses C3 and C4 while the
inverter uses capacitors C1 and C2. Loading
either output decreases both output voltages to
GND because both the doubler and the inverter
circuits use the charge pump. Designers should
not allow the total current output from the doubler
and the inverter to exceed 40mA.
Connecting in Parallel
A designer can parallel a number of SP6830/
6831 devices to reduce the output resistance for
specific designs. All devices will need their own
flying capacitor, C1, but a single output capacitor
will serve all of the devices connected in parallel
by increasing the capacitance of C2 by a factor of
n where n equals the total number of devices
connected. This connection can be found in
Figure 20.
Implementing Shutdown
The SP6830/6831 devices are enabled when the
SHDN input pin is driven HIGH and disabled
when driven LOW. This input must be tied to VIN
or GND to minimize any noise effects due to the
internal switching of these devices. The SHDN
input cannot be driven 0.5V above VIN without
the possibility of introducing significant current
flows.
Cascading Devices
A designer can cascade SP6830/6831 devices to
produce a larger inverted voltage output. Refer
to Figure 21 for this circuit connection. With
two cascaded devices, the unloaded output
voltage is decreased by the output resistance of
the first device multiplied by the quiescent current
of the second device connected. The total output
resistance is greatly increased when more than
two devices are cascaded.
Layout and Grounding
Designers should make an effort to minimize
noise by paying special attention to the circuit
layout with the SP6830/6831 devices. External
components should be connected in close
proximity to the device and a ground plane
should be implemented. This will keep electrical
traces short minimizing parasitic inductance and
capacitance.
Driving Excessive Loads
The output should never be pulled above ground.
A designer should implement a Schottky diode
(1N5817) from OUT to GND when driving
heavy loads where a higher supply is sourcing
current into OUT. Refer to Figure 22 for this
circuit connection.
Rev. 9-22-00
OUT
SP6830/6831 Low Power Voltage Inverters With Shutdown
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© Copyright 2000 Sipex Corporation
C3
+VIN
D1 = D2 = 1N4148
D1
D2
IN
VOUT1
2
C1+
GND
C1
C1Shutdown
Control
Input
SHDN
6
SP6830
SP6831
C4
4
1
3
OUT
VOUT2
5
C2
VOUT1 = (2 x VIN) - VFD1 - VFD2
VOUT2 = -VIN
where
VOUT1 = positive doubled output voltage,
VIN = input voltage,
VFD1 = forward bias voltage across D1,
VFD2 = forward bias voltage across D2, and
VOUT2 = inverted output voltage.
Figure 23. SP6830/6831 Device Connected in a Doubler/Inverter Combination Circuit
Rev. 9-22-00
SP6830/6831 Low Power Voltage Inverters With Shutdown
14
© Copyright 2000 Sipex Corporation
PACKAGE: SOT23-6
b
C
L
e
E
e1
D
C
L
a
C
L
0.20
DATUM 'A'
A A2
C
E1
A
L
2
A1
A
.10
MIN
MAX
A
0.90
1.45
A1
0.00
0.15
A2
0.90
1.30
b
0.25
0.50
C
0.09
0.20
D
2.80
3.10
E
2.60
3.00
E1
1.50
1.75
L
0.35
0.55
SYMBOL
e
0.95ref
e1
1.90ref
a
Rev. 9-22-00
0
O
10
O
SP6830/6831 Low Power Voltage Inverters With Shutdown
15
© Copyright 2000 Sipex Corporation
ORDERING INFORMATION
Model
Temperature Range
Package Type
SP6830EK . ............................................ -40˚C to +85˚C ............................................... SOT23-6
SP6830EK/TR ......................................... -40˚C to +85˚C ............................................... SOT23-6
SP6831EK . ............................................ -40˚C to +85˚C ............................................... SOT23-6
SP6831EK/TR ......................................... -40˚C to +85˚C ............................................... SOT23-6
Please consult the factory for pricing and availability on a Tape-On-Reel option.
Corporation
SIGNAL PROCESSING EXCELLENCE
Sipex Corporation
Headquarters and
Sales Office
22 Linnell Circle
Billerica, MA 01821
TEL: (978) 667-8700
FAX: (978) 670-9001
e-mail: [email protected]
Sales Office
233 South Hillview Drive
Milpitas, CA 95035
TEL: (408) 934-7500
FAX: (408) 935-7600
Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the
application or use of any product or circuit described hereing; neither does it convey any license under its patent rights nor the rights of others.
Rev. 9-22-00
SP6830/6831 Low Power Voltage Inverters With Shutdown
16
© Copyright 2000 Sipex Corporation