ETC HWD2190

HWD2190
1 Watt Audio Power Amplifier
General Description
Key Specifications
The HWD2190 is an audio power amplifier primarily designed
for demanding applications in mobile phones and other portable communication device applications. It is capable of
delivering 1 watt of continuous average power to an 8Ω BTL
load with less than 1% distortion (THD+N) from a 5VDC
power supply.
audio power amplifiers were designed specifically to
provide high quality output power with a minimal amount of
external components. The HWD2190 does not require output
coupling capacitors or bootstrap capacitors, and therefore is
ideally suited for mobile phone and other low voltage applications where minimal power consumption is a primary requirement.
The HWD2190 features a low-power consumption shutdown
mode, which is achieved by driving the shutdown pin with
logic low. Additionally, the HWD2190 features an internal thermal shutdown protection mechanism.
The HWD2190 contains advanced pop & click circuitry which
eliminates noises which would otherwise occur during
turn-on and turn-off transitions.
The HWD2190 is unity-gain stable and can be configured by
external gain-setting resistors.
j PSRR at 217Hz, VDD = 5V (Fig. 1)
62dB(typ.)
j Power Output at 5.0V & 1% THD
1W(typ.)
j Power Output at 3.3V & 1% THD
400mW(typ.)
j Shutdown Current
0.1µA(typ.)
Features
n Available in space-saving packages: micro SMD, MSOP,
SOIC, and LLP
n Ultra low current shutdown mode
n BTL output can drive capacitive loads
n Improved pop & click circuitry eliminates noises during
turn-on and turn-off transitions
n 2.2 - 5.5V operation
n No output coupling capacitors, snubber networks or
bootstrap capacitors required
n Thermal shutdown protection
n Unity-gain stable
n External gain configuration capability
Applications
n Mobile Phones
n PDAs
n Portable electronic devices
Connection Diagrams
8 Bump micro SMD
Top View
Order Number HWD2190IBP, HWD2190IBPX
Connection Diagrams
(Continued)
9 Bump micro SMD
Top View
Order Number HWD2190IBL, HWD2190IBLX
LLP Package
Top View
Order Number HWD2190LD
Mini Small Outline (MSOP) Package
Top View
Order Number HWD2190MM
Small Outline (SO) Package
Top View
Order Number HWD2190M
Connection Diagrams
(Continued)
9 Bump micro SMD
Top View
Order Number HWD2190ITL, HWD2190ITLX
Typical Application
FIGURE 1. Typical Audio Amplifier Application Circuit
Absolute Maximum Ratings
θJA (9 Bump micro SMD, Note 12)
(Note 2)
If Military/Aerospace specified devices are required,
please contact the CSMSC Semiconductor Sales Office/
Distributors for availability and specifications.
Supply Voltage (Note 11)
6.0V
Storage Temperature
−65˚C to +150˚C
−0.3V to VDD +0.3V
Input Voltage
Power Dissipation (Note 3)
Internally Limited
ESD Susceptibility (Note 4)
2000V
Junction Temperature
150˚C
180˚C/W
θJC (MSOP)
56˚C/W
θJA (MSOP)
190˚C/W
θJA (LLP)
220˚C/W
Soldering Information
See AN-1112 "microSMD Wafers Level Chip Scale
Package."
See AN-1187 "Leadless Leadframe Package (LLP)."
Operating Ratings
Thermal Resistance
θJC (SOP)
35˚C/W
θJA (SOP)
150˚C/W
θJA (8 Bump micro SMD, Note 12)
220˚C/W
Temperature Range
TMIN ≤ TA ≤ TMAX
−40˚C ≤ TA ≤ 85˚C
2.2V ≤ VDD ≤ 5.5V
Supply Voltage
Electrical Characteristics VDD = 5V (Notes 1, 2, 8)
The following specifications apply for the circuit shown in Figure 1 unless otherwise specified. Limits apply for TA = 25˚C.
HWD2190
Symbol
IDD
Parameter
Quiescent Power Supply Current
Conditions
Typical
Limit
(Note 6)
(Notes 7, 9)
Units
(Limits)
VIN = 0V, Io = 0A, No Load
4
8
mA (max)
VIN = 0V, Io = 0A, 8Ω Load
5
10
mA (max)
0.1
2.0
µA (max)
ISD
Shutdown Current
VSDIH
Shutdown Voltage Input High
1.2
V (min)
VSDIL
Shutdown Voltage Input Low
0.4
V (max)
VOS
Output Ofsett Voltage
50
mV (max)
9.7
kΩ (max)
7.0
kΩ (min)
VSHUTDOWN = 0V
7
ROUT-GND Resistor Output to GND (Note 10)
Po
Output Power ( 8Ω )
TWU
Wake-up time
TSD
Thermal Shutdown Temperature
8.5
THD = 2% (max); f = 1 kHz
1.0
0.8
W
170
220
ms (max)
170
THD+N
Total Harmonic Distortion+Noise
Po = 0.4 Wrms; f = 1kHz
PSRR
Power Supply Rejection Ratio
(Note 14)
Vripple = 200mV sine p-p
Input Terminated with 10 ohms to
ground
TSDT
Shut Down Time
8 Ω load
150
˚C (min)
190
˚C (max)
0.1
%
62 (f =
217Hz)
66 (f = 1kHz)
55
1.0
dB (min)
ms (max)
Electrical Characteristics VDD = 3V (Notes 1, 2, 8)
The following specifications apply for the circuit shown in Figure 1 unless otherwise specified. Limits apply for TA = 25˚C.
HWD2190
Symbol
Parameter
Conditions
Typical
Limit
Units
(Limits)
(Note 6)
(Notes 7, 9)
IDD
Quiescent Power Supply Current
VIN = 0V, Io = 0A, No Load
3.5
7
mA (max)
VIN = 0V, Io = 0A, 8Ω Load
4.5
9
mA (max)
ISD
Shutdown Current
VSHUTDOWN = 0V
0.1
2.0
µA (max)
VSDIH
Shutdown Voltage Input High
1.2
V(min)
VSDIL
Shutdown Voltage Input Low
0.4
V(max)
VOS
Output Offset Voltage
ROUT-GND Resistor Output to Gnd (Note 10)
TWU
Wake-up time
7
8.5
120
50
mV (max)
9.7
kΩ (max)
7.0
kΩ (min)
180
ms (max)
Electrical Characteristics VDD = 3V (Notes 1, 2, 8)
The following specifications apply for the circuit shown in Figure 1 unless otherwise specified. Limits apply for TA =
25˚C. (Continued)
HWD2190
Symbol
Parameter
Po
Output Power ( 8Ω )
TSD
Thermal Shutdown Temperature
Conditions
THD = 1% (max); f = 1kHz
Limit
(Note 6)
(Notes 7, 9)
0.31
0.28
W
150
˚C(min)
190
˚C(max)
45
dB(min)
170
THD+N
Total Harmonic Distortion+Noise
Po = 0.15Wrms; f = 1kHz
PSRR
Power Supply Rejection Ratio
(Note 14)
Vripple = 200mV sine p-p
Input terminated with 10 ohms to
ground
Units
(Limits)
Typical
0.1
%
56 (f =
217Hz)
62 (f = 1kHz)
Electrical Characteristics VDD = 2.6V (Notes 1, 2, 8)
The following specifications apply for for the circuit shown in Figure 1 unless otherwise specified. Limits apply for TA = 25˚C.
HWD2190
Symbol
Parameter
Conditions
Typical
Limit
(Note 6)
(Notes 7, 9)
Units
(Limits)
IDD
Quiescent Power Supply Current
VIN = 0V, Io = 0A, No Load
2.6
mA (max)
ISD
Shutdown Current
VSHUTDOWN = 0V
0.1
µA (max)
P0
Output Power ( 8Ω )
Output Power ( 4Ω )
THD = 1% (max); f = 1 kHz
THD = 1% (max); f = 1 kHz
0.2
0.22
W
W
THD+N
Total Harmonic Distortion+Noise
Po = 0.1Wrms; f = 1kHz
0.08
%
PSRR
Power Supply Rejection Ratio
(Note 14)
Vripple = 200mV sine p-p
Input Terminated with 10 ohms to
ground
44 (f =
217Hz)
44 (f = 1kHz)
dB
Note 1: All voltages are measured with respect to the ground 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 number given in Absolute Maximum Ratings, whichever is lower. For the HWD2190, see power derating
curves for additional information.
Note 4: Human body model, 100 pF discharged through a 1.5 kΩ resistor.
Note 5: Machine Model, 220 pF–240 pF discharged through all pins.
Note 6: Typicals are measured at 25˚C and represent the parametric norm.
Note 7: Limits are guaranteed to CSMSC’s AOQL (Average Outgoing Quality Level).
Note 8: For micro SMD only, shutdown current is measured in a Normal Room Environment. Exposure to direct sunlight will increase ISD by a maximum of 2µA.
Note 9: Datasheet min/max specification limits are guaranteed by design, test, or statistical analysis.
Note 10: ROUT is measured from each of the output pins to ground. This value represents the parallel combination of the 10k ohm output resistors and the two 20k
ohm resistors.
Note 11: If the product is in shutdown mode and VDD exceeds 6V (to a max of 8V VDD), then most of the excess current will flow through the ESD protection circuits.
If the source impedance limits the current to a max of 10 ma, then the part will be protected. If the part is enabled when VDD is greater than 5.5V and less than 6.5V,
no damage will occur, although operational life will be reduced. Operation above 6.5V with no current limit will result in permanent damage.
Note 12: All bumps have the same thermal resistance and contribute equally when used to lower thermal resistance. All bumps must be connected to achieve
specified thermal resistance.
Note 13: Maximum power dissipation (PDMAX) in the device occurs at an output power level significantly below full output power. PDMAX can be calculated using
Equation 1 shown in the Application section. It may also be obtained from the power dissipation graphs.
Note 14: PSRR is a function of system gain. Specifications apply to the circuit in Figure 1 where AV = 2. Higher system gains will reduce PSRR value by the amount
of gain increase. A system gain of 10 represents a gain increase of 14dB. PSRR will be reduced by 14dB and applies to all operating voltages.
External Components Description
Components
(Figure 1)
Functional Description
1.
RIN
Inverting input resistance which sets the closed-loop gain in conjunction with Rf. This resistor also forms a
high pass filter with CIN at fC= 1/(2π RINCIN).
2.
CIN
Input coupling capacitor which blocks the DC voltage at the amplifier’s input terminals. Also creates a
highpass filter with RIN at fc = 1/(2π RINCIN). Refer to the section, Proper Selection of External
Components, for an explanation of how to determine the value of CIN.
3.
Rf
Feedback resistance which sets the closed-loop gain in conjunction with RIN.
4.
CS
Supply bypass capacitor which provides power supply filtering. Refer to the section, Power Supply
Bypassing, for information concerning proper placement and selection of the supply bypass capacitor,
CBYPASS.
5.
CBYPASS Bypass pin capacitor which provides half-supply filtering. Refer to the section, Proper Selection of External
Components, for information concerning proper placement and selection of CBYPASS.
Typical Performance Characteristics
THD+N vs Frequency
at VDD = 5V, 8Ω RL, and PWR = 250mW, AV = 2
THD+N vs Frequency
at VDD = 3.3V, 8Ω RL, and PWR = 150mW, AV = 2
THD+N vs Frequency
at VDD = 3V, RL = 8Ω, PWR = 250mW, AV = 2
THD+N vs Frequency
THD+N vs Frequency
@ VDD = 2.6V, RL = 8Ω, PWR = 100mW, AV = 2
@ VDD = 2.6V, RL = 4Ω, PWR = 100mW, AV = 2
Typical Performance Characteristics
(Continued)
THD+N vs Power Out
THD+N vs Power Out
@ VDD = 5V, RL = 8Ω, 1kHz, AV = 2
@ VDD = 3.3V, RL = 8Ω, 1kHz, AV = 2
THD+N vs Power Out
@ VDD = 3V, RL = 8Ω, 1kHz, AV = 2
THD+N vs Power Out
THD+N vs Power Out
@ VDD = 2.6V, RL = 8Ω, 1kHz, AV = 2
@ VDD = 2.6V, RL = 4Ω, 1kHz, AV = 2
Typical Performance Characteristics
(Continued)
Power Supply Rejection Ratio (PSRR) @ AV = 2
VDD = 5V, Vripple = 200mvp-p
RL = 8Ω, RIN = 10Ω
Power Supply Rejection Ratio (PSRR) @ AV = 2
VDD = 5V, Vripple = 200mvp-p
RL = 8Ω, RIN = Float
Power Supply Rejection Ratio (PSRR) @ AV = 4
VDD = 5V, Vripple = 200mvp-p
RL = 8Ω, RIN = 10Ω
Power Supply Rejection Ratio (PSRR) @ AV = 4
VDD = 5V, Vripple = 200mvp-p
RL = 8Ω, RIN = Float
Typical Performance Characteristics
(Continued)
Power Supply Rejection Ratio (PSRR) @ AV = 2
VDD = 3V, Vripple = 200mvp-p,
RL = 8Ω, RIN = 10Ω
Power Supply Rejection Ratio (PSRR) @ AV = 2
VDD = 3V, Vripple = 200mvp-p,
RL = 8Ω, RIN = Float
Power Supply Rejection Ratio (PSRR) @ AV = 4
VDD = 3V, Vripple = 200mvp-p,
RL = 8Ω, RIN = 10Ω
Power Supply Rejection Ratio (PSRR) @ AV = 4
VDD = 3V, Vripple = 200mvp-p,
RL = 8Ω, RIN = Float
Power Supply Rejection Ratio (PSRR) @ AV = 2
VDD = 3.3V, Vripple = 200mvp-p,
RL = 8Ω, RIN = 10Ω
Power Supply Rejection Ratio (PSRR) @ AV = 2
VDD = 2.6V, Vripple = 200mvp-p,
RL = 8Ω, RIN = 10Ω
Typical Performance Characteristics
(Continued)
PSRR vs DC Output Voltage
VDD = 5V, AV = 2
PSRR vs DC Output Voltage
VDD = 5V, AV = 4
PSRR vs DC Output Voltage
VDD = 5V, AV = 10
PSRR vs DC Output Voltage
VDD = 3V, AV = 2
PSRR vs DC Output Voltage
VDD = 3V, AV = 4
PSRR vs DC Output Voltage
VDD = 3V, AV = 10
Typical Performance Characteristics
(Continued)
PSRR Distribution VDD = 5V
217Hz, 200mvp-p,
-30, +25, and +80˚C
VDD
Power Supply Rejection Ration vs
Bypass Capacitor Size
= 5V, Input Grounded = 10Ω, Output Load = 8Ω
Top Trace = No Cap, Next Trace Down = 1µf
Next Trace Down = 2µf, Bottom Trace = 4.7µf
HWD2190 vs HWD2177 Power Supply Rejection Ratio
VDD = 5V, Input Grounded = 10Ω
Output Load = 8Ω, 200mV Ripple
HWD2190 = Bottom Trace
HWD2177 = Top Trace
PSRR Distribution VDD = 3V
217Hz, 200mvp-p,
-30, +25, and +80˚C
VDD
Power Supply Rejection Ration vs
Bypass Capacitor Size
= 3V, Input Grounded = 10Ω, Output Load = 8Ω
Top Trace = No Cap, Next Trace Down = 1µf
Next Trace Down = 2µf, Bottom Trace = 4.7µf
HWD2190 vs HWD2177 Power Supply Rejection Ratio
VDD = 3V, Input Grounded = 10Ω
Output Load = 8Ω, 200mV Ripple
HWD2190 = Bottom Trace
HWD2177 = Top Trace
Typical Performance Characteristics
(Continued)
Power Derating Curves (PDMAX = 670mW)
Power Derating - 8 bump µSMD (PDMAX = 670mW)
Ambient Temperature in Degrees C
Note: (PDMAX = 670mW for 5V, 8Ω)
Ambient Temperature in Degrees C
Note: (PDMAX = 670mW for 5V, 8Ω)
Power Derating - 9 bump µSMD (PDMAX = 670mW)
Power Derating - 10 Pin LD Pkg (PDMAX = 670mW)
Ambient Temperature in Degrees C
Note: (PDMAX = 670mW for 5V, 8Ω)
Ambient Temperature in Degrees C
Note: (PDMAX = 670mW for 5V, 8Ω)
Power Output vs Supply Voltage
Power Output vs Temperature
Typical Performance Characteristics
(Continued)
Power Dissipation vs Output Power
VDD = 5V, 1kHz, 8Ω, THD ≤ 1.0%
Power Dissipation vs Output Power
VDD = 3.3V, 1kHz, 8Ω, THD ≤ 1.0%
Power Dissipation vs Output Power
VDD = 2.6V, 1kHz
Output Power
vs Load Resistance
Supply Current
vs Ambient Temperature
Clipping (Dropout) Voltage
vs Supply Voltage
Typical Performance Characteristics
(Continued)
Max Die Temp
at PDMAX (9 bump microSMD)
Max Die Temp
at PDMAX (8 bump microSMD)
Output Offset Voltage
Supply Current
vs Shutdown Voltage
Shutdown Hysterisis Voltage
VDD = 5V
Shutdown Hysterisis Voltage
VDD = 3V
Typical Performance Characteristics
(Continued)
Open Loop Frequency Response
VDD = 5V, No Load
Open Loop Frequency Response
VDD = 3V, No Load
Gain / Phase Response, AV = 2
VDD = 5V, 8Ω Load, CLOAD = 500pF
Gain / Phase Response, AV = 4
VDD = 5V, 8Ω Load, CLOAD = 500pF
Phase Margin vs CLOAD, AV = 2
VDD = 5V, 8Ω Load
Capacitance to gnd on each output
Phase Margin vs CLOAD, AV = 4
VDD = 5V, 8Ω Load
Capacitance to gnd on each output
Typical Performance Characteristics
(Continued)
Phase Margin and Limits
vs Application Variables, RIN = 22KΩ
Wake Up Time (TWU)
Frequency Response
vs Input Capacitor Size
Noise Floor
20019254
20019256
Application Information
BRIDGED CONFIGURATION EXPLANATION
As shown in Figure 1, the HWD2190 has two operational
amplifiers internally, allowing for a few different amplifier
configurations. The first amplifier’s gain is externally configurable, while 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 RIN
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 which results in both
amplifiers producing signals identical in magnitude, but out
of phase by 180˚. Consequently, the differential gain for the
IC is
AVD= 2 *(Rf/RIN)
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 classical 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, as it provides differential
drive to the load, thus doubling 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. This increase in attainable output power assumes
that the amplifier is not current limited or clipped. In order to
choose an amplifier’s closed-loop gain without causing excessive clipping, please refer to the Audio Power Amplifier
Design section.
A bridge configuration, such as the one used in the HWD2190,
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.
EXPOSED-DAP PACKAGE PCB MOUNTING
CONSIDERATIONS FOR THE HWD2190LD
The HWD2190LD’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
HWD2190LD package should have its DAP soldered to the
grounded copper pad (heatsink) under the HWD2190LD (the
NC pins, no connect, and ground pins should also be directly
connected to this copper pad-heatsink area). The area of the
copper pad (heatsink) can be determined from the LD Power
Derating graph. If the multiple layer copper heatsink areas
are used, then these inner layer or backside copper heatsink
areas should be connected to each other with 4 (2 x 2) vias.
The diameter for these vias should be between 0.013 inches
and 0.02 inches with a 0.050inch pitch-spacing. Ensure
efficient thermal conductivity by plating through and solderfilling the vias.
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 HWD2190 has two operational amplifiers in one package, the maximum internal
power dissipation is 4 times that of a single-ended amplifier.
The maximum power dissipation for a given application can
be derived from the power dissipation graphs or from Equation 1.
(1)
PDMAX = 4*(VDD)2/(2π2RL)
It is critical that the maximum junction temperature TJMAX of
150˚C is not exceeded. TJMAX can be determined from the
power derating curves by using PDMAX and the PC board foil
area. By adding additional copper foil, the thermal resistance
of the application can be reduced, resulting in higher PDMAX.
Additional copper foil can be added to any of the leads
connected to the HWD2190. Refer to the APPLICATION INFORMATION on the HWD2190 reference design board for an
example of good heat sinking. If TJMAX still exceeds 150˚C,
then additional changes must be made. These changes can
include reduced supply voltage, higher load impedance, or
reduced ambient temperature. Internal power dissipation is a
function of output power. Refer to the Typical Performance
Characteristics curves for power dissipation information for
different output powers and output loading.
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 the bypass and power supply pins
should be as close to the device as possible. Typical applications employ a 5V regulator with 10 µF tantalum or electrolytic capacitor and a ceramic bypass capacitor which aid
in supply stability. This does not eliminate the need for
bypassing the supply nodes of the HWD2190. The selection of
a bypass capacitor, especially CBYPASS, is dependent upon
PSRR requirements, click and pop performance (as explained in the section, Proper Selection of External Components), system cost, and size constraints.
SHUTDOWN FUNCTION
In order to reduce power consumption while not in use, the
HWD2190 contains a shutdown pin to externally turn off the
amplifier’s bias circuitry. This shutdown feature turns the
amplifier off when a logic low is placed on the shutdown pin.
By switching the shutdown pin to ground, the HWD2190 supply
current draw will be minimized in idle mode. While the device
will be disabled with shutdown pin voltages less than
0.5VDC, the idle current may be greater than the typical
value of 0.1µA. (Idle current is measured with the shutdown
pin grounded).
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 in conjunction with an
external pull-up resistor. When the switch is closed, the
shutdown pin is connected to ground and disables the amplifier. If the switch is open, then the external pull-up resistor
will enable the HWD2190. This scheme guarantees that the
shutdown pin will not float thus preventing unwanted state
changes.
Application Information
(Continued)
SHUTDOWN OUTPUT IMPEDANCE
For Rf = 20k ohms:
ZOUT1 (between Out1 and GND) = 10k||50k||Rf = 6kΩ
produce a virtually clickless and popless shutdown function.
While the device will function properly, (no oscillations or
motorboating), with CBYPASS equal to 0.1µF, the device will
be much more susceptible to turn-on clicks and pops. Thus,
a value of CBYPASS equal to 1.0µF is recommended in all but
the most cost sensitive designs.
AUDIO POWER AMPLIFIER DESIGN
ZOUT2 (between Out2 and GND) = 10k||(40k+(10k||Rf)) =
8.3kΩ
A 1W/8Ω AUDIO AMPLIFIER
Given:
ZOUT1-2 (between Out1 and Out2) = 40k||(10k+(10k||Rf)) =
11.7kΩ
The -3dB roll off for these measurements is 600kHz
PROPER SELECTION OF EXTERNAL COMPONENTS
Proper selection of external components in applications using integrated power amplifiers is critical to optimize device
and system performance. While the HWD2190 is tolerant of
external component combinations, consideration to component values must be used to maximize overall system quality.
The HWD2190 is unity-gain stable which gives the designer
maximum system flexibility. The HWD2190 should be used in
low gain configurations to minimize THD+N values, and
maximize the signal to noise ratio. Low gain configurations
require large input signals to obtain a given output power.
Input signals equal to or greater than 1Vrms are available
from sources such as audio codecs. Please refer to the
section, Audio Power Amplifier Design, for a more complete explanation of proper gain selection.
Besides gain, 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, CIN, 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.
Selection Of Input Capacitor Size
Large input capacitors are both expensive and space hungry
for portable designs. Clearly, a certain sized capacitor is
needed to couple in low frequencies without severe attenuation. But in many cases the speakers used in portable
systems, whether internal or external, have little ability to
reproduce signals below 100Hz to 150Hz. Thus, using a
large input capacitor may not increase actual system performance.
In addition to system cost and size, click and pop performance is effected by the size of the input coupling capacitor,
CIN. A larger 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 size based on necessary low frequency response,
turn-on pops can be minimized.
Besides minimizing the input capacitor size, careful consideration should be paid to the bypass capacitor value. Bypass
capacitor, CBYPASS, is the most critical component to minimize turn-on pops since it determines how fast the HWD2190
turns on. The slower the HWD2190’s outputs ramp to their
quiescent DC voltage (nominally 1/2VDD), the smaller the
turn-on pop. Choosing CBYPASS equal to 1.0µF along with a
small value of CIN, (in the range of 0.1µF to 0.39µF), should
Power Output
1 Wrms
Load Impedance
8Ω
Input Level
1 Vrms
Input Impedance
20 kΩ
100 Hz–20 kHz ± 0.25 dB
Bandwidth
A designer must first determine the minimum supply rail to
obtain the specified output power. By extrapolating from the
Output Power vs Supply Voltage graphs in the Typical Performance Characteristics section, the supply rail can be
easily found. A second way to determine the minimum supply rail is to calculate the required Vopeak using Equation 2
and add the output voltage. Using this method, the minimum
supply voltage would be (Vopeak + (VODTOP + VODBOT)), where
VODBOT and VODTOP are extrapolated from the Dropout Voltage vs Supply Voltage curve in the Typical Performance
Characteristics section.
(2)
5V is a standard voltage which in most applications is chosen for the supply rail. Extra supply voltage creates headroom that allows the HWD2190 to reproduce peaks in excess
of 1W without producing audible distortion. At this time, the
designer must make sure that the power supply choice along
with the output impedance does not violate the conditions
explained in the Power Dissipation section.
Once the power dissipation equations have been addressed,
the required differential gain can be determined from Equation 3.
(3)
Rf/RIN = AVD/2
From Equation 3, the minimum AVD is 2.83; use AVD = 3.
Since the desired input impedance is 20 kΩ, and with an AVD
gain of 3, a ratio of 1.5:1 of Rf to RIN results in an allocation
of RIN = 20 kΩ and Rf = 30 kΩ. The final design step is to
address the bandwidth requirements which must be stated
as a pair of −3 dB frequency points. Five times away from a
−3 dB point is 0.17 dB down from passband response which
is better than the required ± 0.25 dB specified.
fL = 100Hz/5 = 20Hz
fH = 20kHz * 5 = 100kHz
Application Information
(Continued)
As stated in the External Components section, RIN in conjunction with CIN create a highpass filter.
CIN ≥ 1/(2π*20 kΩ*20Hz) = 0.397µF; use 0.39µF
With a AVD = 3 and fH = 100kHz, the resulting GBWP =
300kHz which is much smaller than the HWD2190 GBWP of
2.5MHz. This calculation shows that if a designer has a need
to design an amplifier with a higher differential gain, the
HWD2190 can still be used without running into bandwidth
limitations.
The high frequency pole is determined by the product of the
desired frequency pole, fH, and the differential gain, AVD.
HIGHER GAIN AUDIO AMPLIFIER
FIGURE 2.
The HWD2190 is unity-gain stable and requires no external
components besides gain-setting resistors, an input coupling
capacitor, and proper supply bypassing in the typical application. However, if a closed-loop differential gain of greater
than 10 is required, a feedback capacitor (C4) may be
needed as shown in Figure 2 to bandwidth limit the amplifier.
This feedback capacitor creates a low pass filter that elimi-
nates possible high frequency oscillations. Care should be
taken when calculating the -3dB frequency in that an incorrect combination of R3 and C4 will cause rolloff before
20kHz. A typical combination of feedback resistor and capacitor that will not produce audio band high frequency rolloff
is R3 = 20kΩ and C4 = 25pf. These components result in a
-3dB point of approximately 320 kHz.
Application Information
(Continued)
DIFFERENTIAL AMPLIFIER CONFIGURATION FOR HWD2190
FIGURE 3.
REFERENCE DESIGN BOARD and LAYOUT - micro SMD
FIGURE 4.
Application Information
(Continued)
HWD2190 micro SMD BOARD ARTWORK
Silk Screen
Top Layer
Bottom Layer
Inner Layer VDD
Inner Layer Ground
Application Information
(Continued)
REFERENCE DESIGN BOARD and PCB LAYOUT GUIDELINES - MSOP & SO Boards
FIGURE 5.
Application Information
(Continued)
HWD2190 SO DEMO BOARD ARTWORK
Silk Screen
Top Layer
Top Layer
Bottom Layer
Bottom Layer
HWD2190 MSOP DEMO BOARD ARTWORK
Silk Screen
Application Information
(Continued)
Mono HWD2190 Reference Design Boards
Bill of Material for all 3 Demo Boards
Item
Part Number
1
551011208-001 HWD2190 Mono Reference Design Board 1
Part Description
Qty
Ref Designator
10
212911183-001 HWD2190 Audio AMP
1
U1
20
151911207-001 Tant Cap 1uF 16V 10
1
C1
21
151911207-002 Cer Cap 0.39uF 50V Z5U 20% 1210
1
C2
25
152911207-001 Tant Cap 1uF 16V 10
1
C3
30
472911207-001 Res 20K Ohm 1/10W 5
3
35
210007039-002 Jumper Header Vertical Mount 2X1 0.100 2
PCB LAYOUT GUIDELINES
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.
GENERAL MIXED SIGNAL LAYOUT
RECOMMENDATIONS
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
require a greater amount of design time but will not increase
the final price of the board. The only extra parts required will
be some jumpers.
R1, R2, R3
J1, J2
Single-Point Power / Ground Connections
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 put
digital and analog power traces over the corresponding digital and analog ground traces to minimize noise coupling.
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 cross talk.
Physical Dimensions
inches (millimeters) unless otherwise noted
Note: Unless otherwise specified.
1. Epoxy coating.
2. 63Sn/37Pb eutectic bump.
3. Recommend non-solder mask defined landing pad.
4. Pin 1 is established by lower left corner with respect to text orientation pins are numbered counterclockwise.
5. Reference JEDEC registration MO-211, variation BC.
8-Bump micro SMD
Order Number HWD2190IBP, HWD2190IBPX
X1 = 1.361 ± 0.03
X2 = 1.361 ± 0.03
X3 = 0.850 ± 0.10
Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
9-Bump micro SMD
Order Number HWD2190IBL, HWD2190IBLX
X1 = 1.514 ± 0.03
X2 = 1.514 ± 0.03
X3 = 0.945 ± 0.10
Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
MSOP
Order Number HWD2190MM
Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
SO
Order Number HWD2190M
Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
LLP
Order Number HWD2190LD
Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
9-Bump micro SMD
Order Number HWD2190ITL, HWD2190ITLX
X1 = 1.514 ± 0.03
X2 = 1.514 ± 0.03
X3 = 0.600 ± 0.075
Chengdu Sino Microelectronics System Co.,Ltd
(Http://www.csmsc.com)
Headquarters of CSMSC:
Beijing Office:
Address: 2nd floor, Building D,
Science & Technology
Industrial Park, 11 Gaopeng
Avenue, Chengdu High-Tech
Zone,Chengdu City, Sichuan
Province, P.R.China
PC: 610041
Tel: +86-28-8517-7737
Fax: +86-28-8517-5097
Address: Room 505, No. 6 Building,
Zijin Garden, 68 Wanquanhe
Rd., Haidian District,
Beijing, P.R.China
PC: 100000
Tel: +86-10-8265-8662
Fax: +86-10-8265-86
Shenzhen Office:
Address: Room 1015, Building B,
Zhongshen Garden,
Caitian Rd, Futian District,
Shenzhen, P.R.China
PC: 518000
Tel : +86-775-8299-5149
+86-775-8299-5147
+86-775-8299-6144
Fax: +86-775-8299-6142