NSC LM4961LQ Ceramic speaker driver Datasheet

LM4961
Ceramic Speaker Driver
General Description
Key Specifications
The LM4961 is an audio power amplifier primarily designed
for driving Ceramic Speaker for applications in Cell Phone
and PDAs. It integrates a boost converter, with variable
output voltage, with an audio power amplifier. It is capable of
driving 15Vp-p in BTL mode to 2uF+ 30 ohms load, continuous average power, with less than 1% distortion (THD+N)
from a 3.2VDC power supply.
n Quiescent Power Supply Current
n Voltage Swing in BTL at 1% THD
n Shutdown current
Boomer audio power amplifiers were designed specifically to
provide high quality output power with a minimal number of
external components. The LM4961 does not require bootstrap capacitors, or snubber circuits therefore it is ideally
suited for portable applications requiring high voltage output
to drive capacitive loads like Ceramic Speakers. The
LM4961 features a low-power consumption shutdown mode.
Additionally, the LM4961 features an internal thermal shutdown protection mechanism.
The LM4961 contains advanced pop & click circuitry that
eliminates noises which would otherwise occur during
turn-on and turn-off transitions.
The LM4961 is unity-gain stable and can be configured by
external gain-setting resistors.
7mA (typ)
15Vp-p (typ)
0.1µA (typ)
Features
n Pop & click circuitry eliminates noise during turn-on and
turn-off transitions
n Low current shutdown mode
n Low quiescent current
n Mono 15Vp-p BTL output, RL = 2µF+30Ω, f = 1kHz
n Thermal shutdown protection
n Unity-gain stable
n External gain configuration capability
n Including Band exchange SW
n Including Leakage cut SW
Applications
n Cellphone
n PDA
Connection Diagram
LM4961LQ (5x5)
20094084
Top View
Order Number LM4XXX
See NS Package Number
Boomer ® is a registered trademark of National Semiconductor Corporation.
© 2004 National Semiconductor Corporation
DS200940
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LM4961 Ceramic Speaker Driver
October 2004
LM4961
Typical Application
20094083
* RC is needed for over/under voltage protection. If inputs are less than VDD +0.3V and greater than –0.3V, and if inputs are
disabled when in shutdown mode, then RC can be shorted.
FIGURE 1. Typical Audio Amplifier Application Circuit
Shutdown 1
Shutdown 2
Band-SW
Receiver Mode
—
high
low
Ringer Mode
high
high
high
Shutdown
low
low
—
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2
Junction Temperature
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Thermal Resistance
Supply Voltage (Vdd)
150˚C
θJA (LLP)
66˚C/W
See AN-1187 ’Leadless Leadframe Packaging (LLP).’
6.0V
Amplifier Supply Voltage (V1)
9.5V
Storage Temperature
Operating Ratings
−65˚C to +150˚C
Input Voltage
Temperature Range
−0.3V to VDD + 0.3V
Power Dissipation (Note 3)
Internally limited
ESD Susceptibility (Note 4)
2000V
ESD Susceptibility (Note 5)
200V
TMIN ≤ TA ≤ TMAX
−40˚C ≤ TA ≤ +85˚C
Supply Voltage (VDD)
3.0V < VDD < 5.0V
2.7V < V1 < 9.0V
Amplifier Supply Voltage (V1)
Electrical Characteristics VDD = 4.2V
The following specifications apply for VDD = 4.2V, AV-BTL = 26dB, RL = 2µF+30Ω, Cb = 1.0µF, Band-SW = VDD unless otherwise specified. Limits apply for TA = 25˚C.
Symbol
Parameter
Conditions
LM4961
Typical
(Note 6)
Limit
(Notes 7, 8)
Units
(Limits)
IDD
Quiescent Power Supply Current
VIN = 0V, No Load
Band-SW = VDD
7
14
mA (max)
Iddrcv
Iq in receiver mode
VIN = 0V, No Load
Band-SW = GND
2
4
mA (max)
ISD
Shutdown Current
VSHUTDOWN1 = VSHUTDOWN2 =
GND
Band-SW = GND (Note 9)
0.1
2.0
µA (max)
VLH
Logic High Threshold Voltage
For Shutdown 1, Shutdown 2, and
Band-SW
1.5
V (min)
VLL
Logic Low Threshold Voltage
For Shutdown 1, Shutdown 2, and
Band-SW
0.4
V (max)
RPULLDOWN
Pulldown Resistor
For Shutdown 2 and Band-SW
TSD
Thermal Shutdown Temperature
Vout
Output Voltage Swing
THD = 1%, f = 1kHz
RL = 2µF+30Ω Mono BTL
THD+N
Total Harmomic Distortion + Noise
eOS
50k
Ω (min)
125
˚C (min)
15
14
Vp-p (min)
Vout = 14Vp-p, f = 1kHz
0.05
1.0
% (max)
Output Noise
A-Weighted Filter, VIN = 0V (Note
10)
115
PSRR
Power Supply Rejection Ratio
VRIPPLE = 200mVp-p, f = 100Hz
80
65
dB (min)
Ron-sw-out
On Resistance on SW-Out
Band SW “High” Isink = 100µA
(Between pin 1 and pin 28)
170
220
Ω (max)
70k
µV
Electrical Characteristics VDD = 3.2V
The following specifications apply for VDD = 3.2V, AV-BTL = 26dB, RL = 2µF+30Ω, Cb = 1.0µF, Band-SW = VDD unless otherwise specified. Limits apply for TA = 25˚C.
Symbol
Parameter
Conditions
LM4961
Typical
(Note 6)
Limit
(Notes 7, 8)
Units
(Limits)
IDD
Quiescent Power Supply Current
VIN = 0V, No Load
Band-SW = VDD
9
15
mA (max)
Iddrcv
Iq in receiver mode
VIN = 0V, No Load
Band-SW = GND
2
4
mA (max)
ISD
Shutdown Current
VSHUTDOWN1 = VSHUTDOWN2 =
GND
Band-SW = GND (Note 9)
0.1
2.0
µA (max)
3
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LM4961
Absolute Maximum Ratings (Notes 1, 2)
LM4961
Electrical Characteristics VDD = 3.2V
(Continued)
The following specifications apply for VDD = 3.2V, AV-BTL = 26dB, RL = 2µF+30Ω, Cb = 1.0µF, Band-SW = VDD unless otherwise specified. Limits apply for TA = 25˚C.
Symbol
Parameter
Conditions
LM4961
Typical
(Note 6)
Limit
(Notes 7, 8)
Units
(Limits)
VLH
Logic High Threshold Voltage
For Shutdown 1, Shutdown 2, and
Band-SW
1.5
V (min)
VLL
Logic Low Threshold Voltage
For Shutdown 1, Shutdown 2, and
Band-SW
0.4
V (max)
RPULLDOWN
Pulldown Resistor
For Shutdown 2 and Band-SW
50k
Ω (min)
TSD
Thermal Shutdown Temperature
125
˚C (min)
15
14
Vp-p (min)
1.0
% (max)
70k
Vout
Output Voltage Swing
THD = 1%, f = 1kHz
RL = 2µF+30Ω Mono BTL
THD+N
Total Harmomic Distortion + Noise
Vout = 14Vp-p, f = 1kHz
0.1
eOS
Output Noise
A-Weighted Filter, VIN = 0V (Note
10)
125
PSRR
Power Supply Rejection Ratio
VRIPPLE = 200mVp-p, f = 100Hz
80
65
dB (min)
Ron-sw-out
On Resistance on SW-Out
Band SW “High” Isink = 100µA
(Between pin 1 and pin 28)
170
220
Ω (max)
µV
Note 1: All voltages are measured with respect to the GND pin, unless otherwise specified.
Note 2: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
functional, but do not guarantee specific performance limits. Electrical Characteristics state DC and AC electrical specifications under particular test conditions which
guarantee specific performance limits. This assumes that the device is within the Operating Ratings. Specifications are not guaranteed for parameters where no limit
is given, however, the typical value is a good indication of device performance.
Note 3: The maximum power dissipation must be derated at elevated temperatures and is dictated by TJMAX, θJA, and the ambient temperature, TA. The maximum
allowable power dissipation is PDMAX = (TJMAX − TA) / θJA or the given in Absolute Maximum Ratings, whichever is lower. For the LM4961 typical application (shown
in Figure 1) with VDD = 4.2V, RL = 2µF+30Ω mono BTL operation the maximum power dissipation is 232mW. θJA = 66˚C/W.
Note 4: Human body model, 100pF discharged through a 1.5kΩ resistor.
Note 5: Machine Model, 220pF–240pF discharged through all pins.
Note 6: Typicals are measured at 25˚C and represent the parametric norm.
Note 7: Limits are guaranteed to National’s AOQL (Average Outgoing Quality Level).
Note 8: Datasheet min/max specification limits are guaranteed by design, test, or statistical analysis.
Note 9: Shutdown current is measured in a normal room environment. The Shutdown pin should be driven as close as possible to GND for minimum shutdown
current.
Note 10: Noise measurements are dependent on the absolute values of closed loop gain setting resistors (input and feedback resistors).
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THD+N vs Frequency
VDD = 3.2V, VO = 14VP-P, RL = 2µF+30Ω
THD+N vs Frequency
VDD = 4.2V, VO = 14VP-P, RL = 2µF+30Ω
20094087
200940C3
THD+N vs Output Voltage
VDD = 3.2V, RL = 2µF + 30Ω
THD+N vs Output Voltage
VDD = 4.2V, RL = 2µF + 30Ω
200940C4
200940C5
PSRR vs Frequency
VDD = 4.2V, RL = 8Ω, VRIPPLE = 200mVP-P
PSRR vs Frequency
VDD = 3.2V, RL = 8Ω, VRIPPLE = 20mVP-P
20094089
20094090
5
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LM4961
Typical Performance Characteristics
LM4961
Typical Performance Characteristics
(Continued)
Power Dissipation vs Output Power
VDD = 4.2V, RL = 2µF + 30Ω, f = 1kHz
Power Dissipation vs Output Power
VDD = 3.3V, RL = 2µF + 30Ω, f = 1kHz
20094091
20094092
Frequency Response vs Input Capacitor Size
RL = 8Ω
Supply Current vs Supply Voltage
RL = 2µF + 30Ω, VIN = 0V, RSOURCE = 50Ω
20094093
20094094
Switch Current Limit vs
Duty Cycle
Oscillator Frequency vs
Temperature
20094096
20094095
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6
LM4961
Typical Performance Characteristics
(Continued)
Feedback Voltage vs
Temperature
Feedback Bias Current vs
Temperature
20094097
20094098
Max. Duty Cycle vs
Temperature - ”X”
RDS (ON) vs
Temperature
200940A1
200940A0
RDS (ON) vs
VDD
200940A2
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LM4961
Application Information
where DC is the duty cycle.
BRIDGE CONFIGURATION EXPLANATION
There will be some switching losses as well, so some derating needs to be applied when calculating IC power dissipation.
The Audio Amplifier portion of the LM4961 has two internal
amplifiers allowing different amplifier configurations. The first
amplifier’s gain is externally configurable, whereas the second amplifier is internally fixed in a unity-gain, inverting
configuration. The closed-loop gain of the first amplifier is set
by selecting the ratio of Rf to Ri while the second amplifier’s
gain is fixed by the two internal 20kΩ resistors. Figure 1
shows that the output of amplifier one serves as the input to
amplifier two. This results in both amplifiers producing signals identical in magnitude, but out of phase by 180˚. Consequently, the differential gain for the Audio Amplifier is
TOTAL POWER DISSIPATION
The total power dissipation for the LM4961 can be calculated
by adding Equation 1 and Equation 2 together to establish
Equation 3:
PDMAX(TOTAL) = [4*(VDD)2/
2π ZL]+[DCxIIND(AVE)2xRDS(ON)]
2
(3)
The result from Equation 3 must not be greater than the
power dissipation that results from Equation 4:
AVD = 2 *(Rf/Ri)
PDMAX = (TJMAX - TA) / θJA
By driving the load differentially through outputs Vo1 and
Vo2, an amplifier configuration commonly referred to as
“bridged mode” is established. Bridged mode operation is
different from the classic single-ended amplifier configuration where one side of the load is connected to ground.
A bridge amplifier design has a few distinct advantages over
the single-ended configuration. It provides differential drive
to the load, thus doubling the output swing for a specified
supply voltage. Four times the output power is possible as
compared to a single-ended amplifier under the same conditions.
The bridge configuration also creates a second advantage
over single-ended amplifiers. Since the differential outputs,
Vo1 and Vo2, are biased at half-supply, no net DC voltage
exists across the load. This eliminates the need for an output
coupling capacitor which is required in a single supply,
single-ended amplifier configuration. Without an output coupling capacitor, the half-supply bias across the load would
result in both increased internal IC power dissipation and
also possible loudspeaker damage.
For the LQA28A, θJA = 66˚C/W. TJMAX = 125˚C for the
LM4961. Depending on the ambient temperature, TA, of the
system surroundings, Equation 4 can be used to find the
maximum internal power dissipation supported by the IC
packaging. If the result of Equation 3 is greater than that of
Equation 4, then either the supply voltage must be increased, the load impedance increased or TA reduced. For
the typical application of a 4.2V power supply, with a
2uF+30Ω load, the maximum ambient temperature possible
without violating the maximum junction temperature is approximately 109˚C provided that device operation is around
the maximum power dissipation point. Thus, for typical applications, power dissipation is not an issue. Power dissipation is a function of output power and thus, if typical operation is not around the maximum power dissipation point, the
ambient temperature may be increased accordingly. Refer to
the Typical Performance Characteristics curves for power
dissipation information for lower output levels.
EXPOSED-DAP PACKAGE PCB MOUNTING
CONSIDERATIONS
The LM4961’s exposed-DAP (die attach paddle) package
(LD) provides a low thermal resistance between the die and
the PCB to which the part is mounted and soldered. The low
thermal resistance allows rapid heat transfer from the die to
the surrounding PCB copper traces, ground plane, and surrounding air. The LD package should have its DAP soldered
to a copper pad on the PCB. The DAP’s PCB copper pad
may be connected to a large plane of continuous unbroken
copper. This plane forms a thermal mass, heat sink, and
radiation area. Further detailed and specific information concerning PCB layout, fabrication, and mounting an LD (LLP)
package is found in National Semiconductor’s Package Engineering Group under application note AN1187.
AMPLIFIER POWER DISSIPATION
Power dissipation is a major concern when designing a
successful amplifier, whether the amplifier is bridged or
single-ended. A direct consequence of the increased power
delivered to the load by a bridge amplifier is an increase in
internal power dissipation. Since the amplifier portion of the
LM4961 has two operational amplifiers, the maximum internal power dissipation is 4 times that of a single-ended amplifier. The maximum power dissipation for a given BTL
application can be derived from Equation 1.
(1)
PDMAX(AMP) = 4(VDD)2 / (2π2ZL)
where
ZL = Ro1 + Ro2 +1/2πfc
SHUTDOWN FUNCTION
In many applications, a microcontroller or microprocessor
output is used to control the shutdown circuitry to provide a
quick, smooth transition into shutdown. Another solution is to
use a single-pole, single-throw switch connected between
VDD and Shutdown pins.
BOOST CONVERTER POWER DISSIPATION
At higher duty cycles, the increased ON-time of the switch
FET means the maximum output current will be determined
by power dissipation within the LM4961 FET switch. The
switch power dissipation from ON-time conduction is calculated by Equation 2.
(2)
PDMAX(SWITCH) = DC x IIND(AVE)2 x RDS(ON)
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(4)
BAND SWITCH FUNCTION
The LM4961 features a Band Switch function which allows
the user to use one amplifier for both receiver (earpiece)
mode and ringer/loudspeaker mode. When a logic high
8
REDUCING TRANSIENT CURRENT SPIKE
(Continued)
Due to the quick turn-on time of the Boost Converter, a
transient supply current spike is observed on shutdown release. To reduce the rise time of the output voltage (V1), thus
reducing the value of the supply current spike, please refer
to application circuit in Figure 2. Using this configuration will
allow the user to reduce the transient supply current spike
without the Boost Converter experiencing any stability
issues.
(VDD) is applied to the Band-SW pin (pin 19) the amplifier is
in ringer mode. This enables the boost converter and sets
the externally configurable closed loop gain selection to
BW1. If the Band-SW pin has a logic low (GND) applied to its
terminal then the device is in receiver mode. In this mode the
boost converter is disabled and the gain selection is
switched to BW2. This allows the amplifier to be powered
directly from the battery minus the voltage drop across the
Schottky diode.
200940A3
FIGURE 2. Transient Current Spike Reduction Configuration
PROPER SELECTION OF EXTERNAL COMPONENTS
Proper selection of external components in applications using integrated power amplifiers, and switching DC-DC converters, is critical for optimizing device and system performance. Consideration to component values must be used to
maximize overall system quality.
The best capacitors for use with the switching converter
portion of the LM4961 are multi-layer ceramic capacitors.
They have the lowest ESR (equivalent series resistance)
and highest resonance frequency, which makes them optimum for high frequency switching converters.
When selecting a ceramic capacitor, only X5R and X7R
dielectric types should be used. Other types such as Z5U
9
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LM4961
Application Information
LM4961
Application Information
This feedback capacitor creates a low pass filter that eliminates possible high frequency noise. Care should be taken
when calculating the -3dB frequency because an incorrect
combination of Rf and Cf2 will cause rolloff before the desired frequency
(Continued)
and Y5F have such severe loss of capacitance due to effects
of temperature variation and applied voltage, they may provide as little as 20% of rated capacitance in many typical
applications. Always consult capacitor manufacturer’s data
curves before selecting a capacitor. High-quality ceramic
capacitors can be obtained from Taiyo-Yuden.
SELECTING OUTPUT CAPACITOR (CO) FOR BOOST
CONVERTER
A single 4.7µF to 10µF ceramic capacitor will provide sufficient output capacitance for most applications. If larger
amounts of capacitance are desired for improved line support and transient response, tantalum capacitors can be
used. Aluminum electrolytics with ultra low ESR such as
Sanyo Oscon can be used, but are usually prohibitively
expensive. Typical AI electrolytic capacitors are not suitable
for switching frequencies above 500 kHz because of significant ringing and temperature rise due to self-heating from
ripple current. An output capacitor with excessive ESR can
also reduce phase margin and cause instability.
In general, if electrolytics are used, we recommended that
they be paralleled with ceramic capacitors to reduce ringing,
switching losses, and output voltage ripple.
POWER SUPPLY BYPASSING
As with any amplifier, proper supply bypassing is critical for
low noise performance and high power supply rejection. The
capacitor location on both V1 and VDD pins should be as
close to the device as possible.
SELECTING INPUT CAPACITOR FOR AUDIO
AMPLIFIER
One of the major considerations is the closedloop bandwidth
of the amplifier. To a large extent, the bandwidth is dictated
by the choice of external components shown in Figure 1. The
input coupling capacitor, Ci, forms a first order high pass filter
which limits low frequency response. This value should be
chosen based on needed frequency response for a few
distinct reasons.
High value input capacitors are both expensive and space
hungry in portable designs. Clearly, a certain value capacitor
is needed to couple in low frequencies without severe attenuation. But ceramic speakers used in portable systems,
whether internal or external, have little ability to reproduce
signals below 100Hz to 150Hz. Thus, using a high value
input capacitor may not increase actual system performance.
In addition to system cost and size, click and pop performance is affected by the value of the input coupling capacitor, Ci. A high value input coupling capacitor requires more
charge to reach its quiescent DC voltage (nominally 1/2
VDD). This charge comes from the output via the feedback
and is apt to create pops upon device enable. Thus, by
minimizing the capacitor value based on desired low frequency response, turn-on pops can be minimized.
SELECTING INPUT CAPACITOR (Cs1) FOR BOOST
CONVERTER
An input capacitor is required to serve as an energy reservoir
for the current which must flow into the coil each time the
switch turns ON. This capacitor must have extremely low
ESR, so ceramic is the best choice. We recommend a
nominal value of 4.7µF, but larger values can be used. Since
this capacitor reduces the amount of voltage ripple seen at
the input pin, it also reduces the amount of EMI passed back
along that line to other circuitry.
SETTING THE OUTPUT VOLTAGE (V1) OF BOOST
CONVERTER
The output voltage is set using the external resistors R1 and
R2 (see Figure 1). A value of approximately 13.3kΩ is recommended for R2 to establish a divider current of approximately 92µA. R1 is calculated using the formula:
SELECTING BYPASS CAPACITOR FOR AUDIO
AMPLIFIER
Besides minimizing the input capacitor value, careful consideration should be paid to the bypass capacitor value. Bypass
capacitor, CB, is the most critical component to minimize
turn-on pops since it determines how fast the amplifer turns
on. The slower the amplifier’s outputs ramp to their quiescent DC voltage (nominally 1/2 VDD), the smaller the turn-on
pop. Choosing CB equal to 1.0µF along with a small value of
Ci (in the range of 0.039µF to 0.39µF), should produce a
virtually clickless and popless shutdown function. Although
the device will function properly, (no oscillations or motorboating), with CB equal to 0.1µF, the device will be much
more susceptible to turn-on clicks and pops. Thus, a value of
CB equal to 1.0µF is recommended in all but the most cost
sensitive designs.
R1 = R2 X (V2/1.23 − 1)
FEED-FORWARD COMPENSATION FOR BOOST
CONVERTER
Although the LM4961’s internal Boost converter is internally
compensated, the external feed-forward capacitor Cf is required for stability (see Figure 1). Adding this capacitor puts
a zero in the loop response of the converter. The recommended frequency for the zero fz should be approximately
6kHz. Cf1 can be calculated using the formula:
Cf1 = 1 / (2 X R1 X fz)
(6)
SELECTING DIODES
The external diode used in Figure 1 should be a Schottky
diode. A 20V diode such as the MBR0520 from Fairchild
Semiconductor is recommended.
The MBR05XX series of diodes are designed to handle a
maximum average current of 0.5A. For applications exceeding 0.5A average but less than 1A, a Microsemi UPS5817
can be used.
SELECTING FEEDBACK CAPACITOR FOR AUDIO
AMPLIFIER
The LM4961 is unity-gain stable which gives the designer
maximum system flexability. However, to drive ceramic
speakers, a typical application requires a closed-loop differential gain of 10. In this case a feedback capacitor (Cf2) will
be needed as shown in Figure 1 to bandwidth limit the
amplifier.
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(5)
10
LM4961
Application Information
(Continued)
DUTY CYCLE
The maximum duty cycle of the boost converter determines
the maximum boost ratio of output-to-input voltage that the
converter can attain in continuous mode of operation. The
duty cycle for a given boost application is defined as:
Duty Cycle = VOUT + VDIODE - VIN / VOUT + VDIODE - VSW
This applies for continuous mode operation.
20094099
INDUCTANCE VALUE
FIGURE 3. 10µH Inductor Current
5V - 12V Boost (LM4961X)
The first question we are usually asked is: “How small can I
make the inductor.” (because they are the largest sized
component and usually the most costly). The answer is not
simple and involves trade-offs in performance. Larger inductors mean less inductor ripple current, which typically means
less output voltage ripple (for a given size of output capacitor). Larger inductors also mean more load power can be
delivered because the energy stored during each switching
cycle is:
During the 0.390µs ON-time, the inductor current ramps up
0.176A and ramps down an equal amount during the OFFtime. This is defined as the inductor “ripple current”. It can
also be seen that if the load current drops to about 33mA,
the inductor current will begin touching the zero axis which
means it will be in discontinuous mode. A similar analysis
can be performed on any boost converter, to make sure the
ripple current is reasonable and continuous operation will be
maintained at the typical load current values. Taiyo-Yudens
NR4012 inductor series is recommended.
E = L/2 X (lp)2
Where “lp” is the peak inductor current. An important point to
observe is that the LM4961 will limit its switch current based
on peak current. This means that since lp(max) is fixed,
increasing L will increase the maximum amount of power
available to the load. Conversely, using too little inductance
may limit the amount of load current which can be drawn
from the output.
Best performance is usually obtained when the converter is
operated in “continuous” mode at the load current range of
interest, typically giving better load regulation and less output ripple. Continuous operation is defined as not allowing
the inductor current to drop to zero during the cycle. It should
be noted that all boost converters shift over to discontinuous
operation as the output load is reduced far enough, but a
larger inductor stays “continuous” over a wider load current
range.
To better understand these trade-offs, a typical application
circuit (5V to 12V boost with a 10µH inductor) will be analyzed. We will assume:
MAXIMUM SWITCH CURRENT
The maximum FET switch current available before the current limiter cuts in is dependent on duty cycle of the application. This is illustrated in a graph in the typical performance characterization section which shows typical values
of switch current as a function of effective (actual) duty cycle.
CALCULATING OUTPUT CURRENT OF BOOST
CONVERTER (IAMP)
As shown in Figure 2 which depicts inductor current, the load
current is related to the average inductor current by the
relation:
ILOAD = IIND(AVG) x (1 - DC)
(7)
Where "DC" is the duty cycle of the application. The switch
current can be found by:
ISW = IIND(AVG) + 1/2 (IRIPPLE)
(8)
VIN = 5V, VOUT = 12V, VDIODE = 0.5V, VSW = 0.5V
Inductor ripple current is dependent on inductance, duty
cycle, input voltage and frequency:
Since the frequency is 1.6MHz (nominal), the period is approximately 0.625µs. The duty cycle will be 62.5%, which
means the ON-time of the switch is 0.390µs. It should be
noted that when the switch is ON, the voltage across the
inductor is approximately 4.5V. Using the equation:
IRIPPLE = DC x (VIN-VSW) / (f x L)
(9)
combining all terms, we can develop an expression which
allows the maximum available load current to be calculated:
V = L (di/dt)
ILOAD(max) = (1–DC)x(ISW(max)–DC(VIN-VSW))/2FL(10)
We can then calculate the di/dt rate of the inductor which is
found to be 0.45 A/µs during the ON-time. Using these facts,
we can then show what the inductor current will look like
during operation:
The equation shown to calculate maximum load current
takes into account the losses in the inductor or turn-OFF
switching losses of the FET and diode.
11
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LM4961
Application Information
GENERAL MIXED-SIGNAL LAYOUT
RECOMMENDATION
(Continued)
DESIGN PARAMETERS VSW AND ISW
The value of the FET "ON" voltage (referred to as VSW in
equations 7 thru 10) is dependent on load current. A good
approximation can be obtained by multiplying the "ON Resistance" of the FET times the average inductor current.
FET on resistance increases at VIN values below 5V, since
the internal N-FET has less gate voltage in this input voltage
range (see Typical Performance Characteristics curves).
Above VIN = 5V, the FET gate voltage is internally clamped
to 5V.
This section provides practical guidelines for mixed signal
PCB layout that involves various digital/analog power and
ground traces. Designers should note that these are only
"rule-of-thumb" recommendations and the actual results will
depend heavily on the final layout.
Power and Ground Circuits
For 2 layer mixed signal design, it is important to isolate the
digital power and ground trace paths from the analog power
and ground trace paths. Star trace routing techniques (bringing individual traces back to a central point rather than daisy
chaining traces together in a serial manner) can have a
major impact on low level signal performance. Star trace
routing refers to using individual traces to feed power and
ground to each circuit or even device. This technique will
take require a greater amount of design time but will not
increase the final price of the board. The only extra parts
required may be some jumpers.
The maximum peak switch current the device can deliver is
dependent on duty cycle. For higher duty cycles, see Typical
Performance Characteristics curves.
INDUCTOR SUPPLIERS
The recommended inductors for the LM4961 is the TaiyoYuden NR4012. When selecting an inductor, make certain
that the continuous current rating is high enough to avoid
saturation at peak currents. A suitable core type must be
used to minimize core (switching) losses, and wire power
losses must be considered when selecting the current rating.
Single-Point Power / Ground Connection
The analog power traces should be connected to the digital
traces through a single point (link). A "Pi-filter" can be helpful
in minimizing high frequency noise coupling between the
analog and digital sections. It is further recommended to
place digital and analog power traces over the corresponding digital and analog ground traces to minimize noise coupling.
PCB LAYOUT GUIDELINES
High frequency boost converters require very careful layout
of components in order to get stable operation and low
noise. All components must be as close as possible to the
LM4961 device. It is recommended that a 4-layer PCB be
used so that internal ground planes are available. See Figures 4–7 for demo board reference schematic and layout.
Some additional guidelines to be observed:
1. Keep the path between L1, D1, and Co extremely short.
Parasitic trace inductance in series with D1 and Co will
increase noise and ringing.
2. The feedback components R1, R2 and Cf 1 must be kept
close to the FB pin of U1 to prevent noise injection on the FB
pin trace.
3. If internal ground planes are available (recommended)
use vias to connect directly to ground at pin 2 of U1, as well
as the negative sides of capacitors Cs1 and Co.
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Placement of Digital and Analog Components
All digital components and high-speed digital signals traces
should be located as far away as possible from analog
components and circuit traces.
Avoiding Typical Design / Layout Problems
Avoid ground loops or running digital and analog traces
parallel to each other (side-by-side) on the same PCB layer.
When traces must cross over each other do it at 90 degrees.
Running digital and analog traces at 90 degrees to each
other from the top to the bottom side as much as possible will
minimize capacitive noise coupling and crosstalk.
12
LM4961
Schematic Board Layout
200940A4
FIGURE 4. Demo Board Schematic
13
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LM4961
Demonstration Board Layout
200940C1
FIGURE 5. Recommended TS SE PCB Layout:
Top Silkscreen
200940C0
FIGURE 6. Recommended TS SE PCB Layout:
Top Layer
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14
LM4961
Demonstration Board Layout
(Continued)
200940C2
FIGURE 7. Recommended TS SE PCB Layout:
Bottom Layer
15
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LM4961 Ceramic Speaker Driver
Physical Dimensions
inches (millimeters) unless otherwise noted
LQ Package
Order Number LM4961LQ
NS Package Number LQA28A
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS
WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL COUNSEL OF NATIONAL SEMICONDUCTOR
CORPORATION. As used herein:
1. Life support devices or systems are devices or systems
which, (a) are intended for surgical implant into the body, or
(b) support or sustain life, and whose failure to perform when
properly used in accordance with instructions for use
provided in the labeling, can be reasonably expected to result
in a significant injury to the user.
2. A critical component is any component of a life support
device or system whose failure to perform can be reasonably
expected to cause the failure of the life support device or
system, or to affect its safety or effectiveness.
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Specification (CSP-9-111C2) and the Banned Substances and Materials of Interest Specification (CSP-9-111S2) and contain no ‘‘Banned
Substances’’ as defined in CSP-9-111S2.
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