VISHAY SI9161

Si9161
Vishay Siliconix
Si9161
Optimized-Efficiency Controller for RF Power
Amplifier Boost Converter
FEATURES
• Si9160 architecture optimized for “light-load” efficiency
• High Frequency Switching (up to 2 MHz)
• Optimized Output Drive Current (300 mA)
• Standby Mode
• Wide Bandwidth Feedback Amplifier
• Single-Cell LiIon and Three-cell NiCd or NiMH Operation
DESCRIPTION
The Si9161 Optimized-Efficiency Controller for RF Power
Amplifier Boost Converter is a fixed-frequency, pulse- widthmodulated power conversion controller designed for use with
the Si6801 application specific MOSFET. The Si9161 and the
Si6801 are optimized for high efficiency switched-mode power
conversion at 1 MHz and over. The device has an enable pin
which can be used to put the converter in a low-current mode
compatible with the standby mode of most cellular phones. It
has a light-load pin which enables circuitry optimizing
efficiency at loads typical of receive operation. A wide
bandwidth feedback amplifier minimizes transient response
time allowing the device to meet the instantaneous current
demands of today’s digital protocols. The input voltage range
accommodates minimal size and cost battery pack
configurations.
Frequency control in switching is important to noise
management techniques in RF communications. The Si9161
is easily synchronized for high efficiency power conversion at
frequencies in excess of 1 MHz.
Optimizing the controller and the synchronous FETs results in
the highest conversion efficiency over a wide load range at the
switching frequencies of interest (1 MHz or greater). It also
minimizes the overshoot and gate ringing associated with
drive current and gate charge mismatches.
When disabled, the converter requires less than 330 µA. This
capability minimizes the impact of the converter on battery life
when the phone is in the standby mode.
Finally, operating voltage is optimized for LiIon battery
operation (2.7 V to 4.5 V) and can also be used with three-cell
NiCd or NiMH (3 V to 3.6 V), as well as four-cell NiCd or NiMH
(4 V to 4.8 V) battery packs.
APPLICATION CIRCUIT
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ABSOLUTE MAXIMUM RATINGS
Voltages Referenced to GND.
Operating Junction Temperature . . . . . . . . . . . . . . . . . . . . . . . . 150°C
VDD, VS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 V
Power Dissipation (Package)a
16-Pin TSSOP (Q Suffix)a, b . . . . . . . . . . . . . . . . . . . . . . . . . 925 mW
PGND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±0.3 V
Linear Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 V to VDD +0.3 V
Logic Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 V to VDD +0.3 V
Peak Output Drive Current . . . . . . . . . . . . . . . . . . . . . . . . . . . 350 mA
Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . -65 to 150°C
Thermal Impedance (ΘJA)a
16-Pin TSSOP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .135°C/W
Notes
a. Device mounted with all leads soldered or welded to PC board.
b. Derate 7.4 mW/°C above 25°C.
Exposure to Absolute Maximum rating conditions for extended periods may affect device reliability. Stresses above Absolute Maximum rating may cause permanent
damage. Functional operation at conditions other than the operating conditions specified is not implied. Only one Absolute Maximum rating should be applied at any
one time.
SPECIFICATIONS
Limits
Test Conditions
Unless Otherwise Specifieda
Parameter
Symbol
LL = VDD, 2.7 V ≤ VDD, VS ≤ 6.0 V, GND = PGND
B Suffix -25 to 85°C
Minb
Typ
Maxb
1.50
1.523
Unit
Reference
Output Voltage
IREF = -10 µA
VREF
1.455
TA = 25°C
1.477
1.545
V
Oscillator
Maximum Frequencyc
fMAX
Oscillator Frequency
Accuracy
ROSC Peak Voltage
Voltage Stabilityc
Temperature Stabilityc
Light-Load Frequencyc
VDD = 5 V, COSC = 47 pF, ROSC = 5.0 kΩ
2.0
VDD = 3.0 V, fOSC = 1 MHz (nominal)
COSC = 100 pF, ROSC = 7.0 kΩ, TA = 25°C
-15
4 V ≤ VDD ≤ 6 V, Ref to 5 V, TA = 25°C
-8
VROSC
∆f/f
fLL
MHz
15
1.0
V
8
Referenced to 25°C
±5
LL = 0 V, COSC = 100 pf, ROSC = 7.0 kΩ
115
%
%
kHz
Error Amplifier (COSC = GND, OSC Disabled)
Input Bias Current
IB
Open Loop Voltage Gain
AVOL
Offset Voltage
VOS
Unity Gain Bandwidthc
BW
Output Current
Power Supply Rejectionc
IOUT
VNI = VREF , VFB = 1.0 V
-1.0
47
55
VNI = VREF
-15
0
1.0
µA
15
mV
dB
10
Source (VFB = 1 V, NI = VREF)
Sink (VFB = 2 V, NI = VREF)
PSRR
4 V < VDD < 6 V
-2.0
0.4
MHz
-1.0
0.8
60
mA
dB
UVLOSET Voltage Monitor
Under Voltage Lockout
Hysteresis
UVLO Input Current
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VUVLOHL
UVLOSET High to Low
VUVLOLH
UVLOSET Low to High
VHYS
VUVLOLH - VUVLOHL
IUVLO(SET)
VUVLO = 0 to VDD
0.85
1.0
1.15
1.2
200
-100
V
mV
100
nA
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SPECIFICATIONS
Limits
Test Conditions
Unless Otherwise Specifieda
Parameter
Symbol
LL = VDD, 2.7 V ≤ VDD, VS ≤ 6.0 V, GND = PGND
B Suffix -25 to 85°C
Minb
Typ
5.15
5.2
Maxb
Unit
Output Drive (DR and DS)
Output High Voltage
VOH
Output Low Voltage
VOL
Peak Source Output Current
VDD = 2.7 V
VS = 5.3 V
ISOURCE
IOUT = -10
mA
V
IOUT = 10 mA
0.06
0.15
VS = 5.3 V
-300
-250
VDD = 2.7 V
VS = 5.3 V
250
300
Peak Sink Output Current
ISINK
Break-Before-Make
tBBM
VDD = 6.0 V
40
ENABLE Rising to OUTPUT, VDD = 6.0 V
1.4
mA
ns
Logic
ENABLE Delay to Output
tdEN
ENABLE Logic Low
VENL
ENABLE Logic High
VENH
ENABLE Input Current
Light Load Delay to Output
c
ENABLE = 0 to VDD
tdLL
Light Load Falling to OUTPUTS
VLLL
Light Load Logic High
VLLH
Light Load Input Current
V
0.8 VDD
IEN
Light Load Logic Low
µs
0.2 VDD
-1.0
1.0
µA
1.4
µs
0.8
V
2.4
ILL
LL = 0 to VDD
CYCLEMAX
VDD = 6.0 V
IDMAX
DMAX = 0 to VDD
-1.0
1.0
µA
95
%
100
nA
Duty Cycle
Maximum Duty Cycle
DMAX/SS Input Current
80
-100
Supply
Supply Current—Normal
Mode
IDD
No Load, VLL = 0 to VDD
fOSC = 1 MHz, ROSC = 7.0 kΩ
Supply Current—Standby
Mode
ENABLE = Low
VDD = 2.7 V
1.1
1.5
VDD = 4.5 V
1.6
2.3
250
330
mA
µA
Notes
a. CSTRAY < 5 pF on COSC. After Start-Up, VDD of ≥ 3 V.
b. The algebraic convention whereby the most negative value is a minimum and the most positive a maximum, is used in this data sheet.
c. Guaranteed by design, not subject to production testing.
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TYPICAL CHARACTERISTICS (LL = VDD, 25°C UNLESS OTHERWISE NOTED)
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TYPICAL CHARACTERISTICS (LL = VDD, 25°C UNLESS OTHERWISE NOTED)
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PIN CONFIGURATIONS
PIN DESCRIPTION
Pin 1: VDD
The positive power supply for all functional blocks except
output driver. A bypass capacitor of 0.1 µF (minimum) is
recommended.
Pin 2: LL
A logic high on this pin allows normal operation. A logic low
places the chip in light-load optimized-efficiency mode. In
light-load mode, the oscillator frequency is reduced and DR
goes high, disabling synchronous rectification. Do not leave
pin unconnected.
Pin 8: GND (Ground)
Pin 9: ENABLE
A logic high on this pin allows normal operation. A logic low
places the chip in the standby mode. In standby mode, normal
operation is disabled, supply current is reduced, the oscillator
stops, and DS goes low while DR goes high.
Pin 10: ROSC
A resistor connected from this pin to ground sets the
oscillator’s capacitor (COSC) charge and discharge current.
See the oscillator section of the description of operation.
Pin 3: DMAX
Used to set the maximum duty cycle.
Pin 11: COSC
Pin 4: COMP
An external capacitor is connected to this pin to set the
normal oscillator frequency.
This pin is the output of the error amplifier. A compensation
network is connected from this pin to the FB pin to stabilize
the system. This pin drives one input of the internal pulse
width modulation comparator.
0.70
f OSC ≅ -----------------------------------R OSC × C OSC
(at VDD = 5.0 V)
Pin 12: UVLOSET
Pin 5: FB
The inverting input of the error amplifier. An external resistor
divider is connected to this pin to set the regulated output
voltage. The compensation network is also connected to this
pin.
This pin will place the chip in the standby mode if the
UVLOSET voltage drops below 1.2 V. Once the UVLOSET
voltage exceeds 1.2 V, the chip operates normally. There is a
built-in hysteresis of 200 mV.
Pin 13: PGND
Pin 6: NI
The non-inverting input of the error amplifier. In normal
operation it is externally connected to VREF or an external
reference.
Pin 7: VREF
This pin supplies a 1.5-V reference.
S-60752—Rev. B, 05-Apr-99
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The negative return for the VS supply.
Pin 14: DS
This CMOS push-pull output pin drives the external n-channel
MOSFET. This pin will be low in the standby mode. A breakbefore-make function between DS and DR is built-in.
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Pin 15: DR
Pin 16: VS
This CMOS push-pull output pin drives the external p-channel
MOSFET. This pin will be high in the standby and light-load
modes. A break-before-make function between the DS and DR
is built-in.
The positive terminal of the power supply which powers the
CMOS output drivers. A bypass capacitor is required.
FUNCTIONAL BLOCK DIAGRAM
TIMING WAVEFORMS
Note: Timing waveforms are not to scale.
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OPERATION OF THE Si9161 BOOST CONVERTER
The Si9161 combined with optimized complementary
MOSFETs provides the ideal solution to small, high efficiency,
synchronous boost power conversion. Optimized for a 1-cell
lithium ion, or 3-cell to 4-cell Nickel metal hydride battery, it is
capable of switching at frequencies of up to 2 MHz. Combined
with the Si6801, a complimentary high-frequency MOSFET,
efficiencies of over 90% are easily achieved in a very small
area; with light-load mode, efficiency over 80% can be
achieved at power less than 1/2 W.
PWM Controller
The Si9161 implements a user-selectable synchronous/nonsynchronous voltage mode PWM control topology and is
especially designed for battery power conversion. Voltagemode control results in the most efficient power conversion
solution. Figure 1 below illustrates a schematic for a
synchronous boost converter with an input range of 2.7 V to
5 V which covers the range of 1-cell LiIon and 3-cell or 4-cell
NiMH/NiCd battery input respectively, and an output voltage of
5 V. Note the maximum input voltage is limited to the output
voltage for a boost converter.
The switching frequency is determined by an external
capacitor and resistor connected to Cosc and Rosc pins. The
graph on page 5 in the Typical Characteristics section shows
the typical Cosc and Rosc values for various switching
frequency. Si9161 oscillator frequency can be easily
synchronized to external frequency as long as external
switching frequency is higher than the internal oscillator
frequency. The synchronization circuit is a series resistor and
capacitor fed into the Cosc pin of the Si9161. The
synchronization pulse should be greater than 1.5 V in
amplitude and a near square wave pulsed clock. Figure 1
shows typical values for the synchronization components.
FIGURE 1. Si9161 Boost Converter
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Startup
Designed to operate with single cell Lithium Ion battery
voltage, the Si9161 has an operating range of 2.7 V to 6.0 V.
During start-up, the device requires 3.0 V to guarantee proper
operation, although it will typically start up at less than 2.2 V.
Once powered, Si9161 will continue to operate until the
voltage at VDD is 2.7 V; at this point, the battery is basically
dead. During start-up, power for the chip is provided by the
battery through R5 to VDD and through schottky diode D1 to
VS pins. Once the converter is fully operating, VS supply
power is provided by the converter output through diode D2,
which overrides the D1 diode. This self perpetuating method
of powering further improves the converter efficiency by
utilizing higher gate drive to lower the on-resistance loss of
the MOSFET.
Another benefit of powering from the output voltage is it
provides minimum load on the converter. This prevents the
converter from skipping frequency pulses typically referred to
as Burst or Pulse-Skipping modes. Pulse skipping mode could
be dangerous, especially if it generates noise in RF, IF, or
signal processing frequency bands.
Enable and Under Voltage Shutdown
The Si9161 is designed with programmable under-voltage
lockout and enable features. These features give designers
flexibility to customize the converter design. The undervoltage lockout threshold is 1.2 V. With a simple resistor
divider from VDD, Si9161 can be programmed to turn-on at
any VDD voltage. The ENABLE pin, a TTL logic compatible
input, allows remote shutdown as needed.
FIGURE 2. Gate Drive Timing Diagrams
The MOSFET used is the Si6801, an n- and p-channel in a
single package TSSOP-8. The Si6801 is optimized to have
very low gate charge and gate resistance. This results in a
great reduction in gate switching power losses. The average
time to switch on and off a MOSFET in a conventional
structure is about 20 ns. The Si6801 will switch on and off in
<5 ns, see Figure 3.
Gate Drive and MOSFETs
The gate drive section is designed to drive the high-side
p-channel switch and low-side n-channel switch. The internal
40 ns break-before-make (BBM) timing prevents both
MOSFETs from turning-on simultaneously. The BBM circuit
monitors both drive voltages, once the gate-to-source voltage
drops below 2.5 V, the other gate drive is delayed 40-ns
before it is allowed to drive the external MOSFET (see
Figure 2 for timing diagram). This smart gate drive control
provides additional assurance that shoot-through current will
not occur.
Note the Speed
These MOSFETs have switching speeds of <5 ns. This high speed is
due to the fast, high current output drive of the Si9161 and the
optimized gate charge of the Si6801.
FIGURE 3. Gate Switching Times
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Stability Components
A voltage mode boost converter is normally stabilized with
simple lag compensation due to the additional 90° phase lag
introduced by the additional right hand plane zero, as well as
having a duty factor dependent resonant frequency for the
output filter. The stability components shown in Figure 1 have
been chosen to ensure stability under all battery conditions
while maintaining maximum transient response. To do this we
have used simple lag compensation (type 1 amplifier
configuration). Figure 4 shows the bode plot for the above
circuit, maintaining > 50° phase margin over the entire battery
voltage range.
The inductance value for the converter is a function of the
desired ripple voltage and efficiency as stated below. In order
to keep the ripple small and improve efficiency, the inductance
needs to be large enough to maintain continuous current
mode. Continuous current mode has lower RMS current
compared to discontinuous current mode since the peak
current is lower. This lowers the conduction loss and improves
efficiency. The equation that shows the critical inductance
which separates continuous and discontinuous current mode
at any given output current is stated below. This equation is
also plotted in Figure 5 as a function of input voltage.
2
V IN ⋅ ( V OUT – V IN ) ⋅ η
L = ------------------------------------------------------2
2 ⋅ V OUT ⋅ I OUT ⋅ f
η = efficiency
FIGURE 4. Stability, with 1-cell Li battery input, 5 V @
600-mA output.
Energy Storage Components
The input and output ripple voltage is determined by the
switching frequency, and the inductor and capacitor values.
The higher the frequency, inductance, or capacitance values,
the lower the ripple. The efficiency of the converter is also
improved with higher inductance by reducing the conduction
loss in the switch, synchronous rectifier, and the inductor
itself. In the past, Tantalum was the preferred material for the
input and output capacitors. Now, with 2-MHz switching
frequencies, Tantalum capacitors are being replaced with
smaller surface mount ceramic capacitors. Ceramic
capacitors have almost no equivalent series resistance (ESR).
Tantalum capacitors have at least 0.1-Ω ESR. By reducing
ESR, converter efficiency is improved while decreasing the
input and output ripple voltage. With ceramic capacitors,
output ripple voltage is a function of capacitance only. The
equation for determining output capacitance is stated below.
I OUT ⋅ ( V OUT – V IN )
C = --------------------------------------------------V OUT ⋅ ∆V RIPPLE ⋅ f
IOUT
VOUT
VIN
∆VRIPPLE
f
=
=
=
=
=
output dc load current
output voltage
input voltage
desired output ripple voltage
switching frequency
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FIGURE 5. Continous and Discontinous Inductance Curve
Designed with small surface mount inductors and capacitors,
the Si9161 solution can fit easily within a small space such as
a battery pack. Another distinct advantage of a smaller
converter size is that it reduces the noise generating area by
reducing the high current path; therefore radiated and
conducted noise is less likely to couple into sensitive circuits.
RESULTS SECTION
The following section shows the actual results obtained with
the circuit diagram shown in Figure 1.
Efficiency
The graph below shows the efficiency of the above design at
various constant switching frequencies. The frequencies were
generated using a 3-V square wave of the desired frequency
to the sync input to the circuit. The input voltage to the circuit
is 3.6-V dc.
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FIGURE 6. Efficiency of Si9161 and Si6801 Boost converter
at various fixed frequencies
Output Noise
The noise generated by a dc-dc converter is always an issue
within the mobile phone. The Si9161 offers two benefits.
1. The noise spectrum is a constant, i.e. no random noise or
random harmonic generation.
2. The switching fundamental can be synchronized to a
known frequency, e.g. 812.5 kHz which is ¹|₁₆-th of the
GSM/DCS system clock, or 1.23 MHz which is the channel
spacing frequency for CDMA, etc.
FIGURE 7. Output noice of the Si9160 demo board
Figures 7 through 9 show the output noise and output
spectrum analysis.
Output Noise Spectrum
Note there is no random noise, only switching frequency
harmonics. This is very good news for the RF stages, where
an unknown, or random noise spectrum will cause problems.
FIGURE 8. Spectrum response for the Si9161 demo board output voltage
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FIGURE 9. Higher resolution of noise spectrum
Conclusion
Switching at high, known frequencies results in a smaller
footprint while maintaining high efficiency. Efficiencies at high
switching frequencies can be improved by using Si6801
optimized low gate charge and low gate resistance MOSFET.
Even though the high frequency MOSFET has been designed
with minimum gate charge, it still presents significant power
loss during the light load conditions. In order to minimize this
switching loss, Si9161 is designed with a light load efficiency
S-60752—Rev. B, 05-Apr-99
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improvement pin which decreases the switching frequency by
8.5 times (@ 1 MHz) and disables the synchronous
rectification. This feature improves the light load efficiency in
certain conditions as much as 50% compare to Si9160.
Additionally, under transmitting mode, Si9161 clock frequency
can be synchronized to higher external frequency which
eliminates or greatly reduces any radio interference concerns
and pushes harmonics out beyond signal processing
frequencies.
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