YAMAHA YDA135

YDA135
D-20
STEREO 5W-20W DIGITAL AUDIO POWER AMPLIFIER CONTROLLER
Outline
YDA135 is digital audio power amplifier controller IC that is output power of 20W/channel on a 12V power supply
operation.
This IC is combined with the general purpose Power MOSFET (hereafter called Power MOSFET) that are
connected through BTL can configure an audio power amplifier with output power of 5W or 20W.
This IC accepts analog signal, converts it into digital pulse signal by the digital modulation circuitry and outputs
the digital pulse signal for driving Power MOSFET. The Power MOSFET that is driven by this IC outputs large
current digital pulses. The digital pulse signal is converted to audio signal through an external low pass filter, and
sent to the speakers.
By using a general purpose Power MOSFET, very low cost digital amplifier system is configured. By adapting
Yamaha's proprietary modulation system, the device provides low distortion and high signal to noise ratio at the
highest level among digital amplifiers in the equiralent class.
This IC has the overcurrent detection function that detects overcurrent state by voltage drop of external resistors
that detects the output current.
This IC has the high temperature detection function that detects high temperature by resistor value change of
external element that detects temperature.
The operation of this IC is limited by using two control signal, SLEEP or MUTE. SLEEP signal stops all functions
of this IC, and restrain to the power consumption at the minimum. MUTE signal brings Power MOSFET into
nonconductive state, and mute the output of the device.
This IC is configured by two power supply ; 5V for signal processing circuits, and 12V for Power MOSFET driving
circuits.
Features
・Highoutputpower
20W＠VDDP=12.0VRL=4ΩTHD+N<10%
・Highefficiencyoperation
80%＠VDDP=12.0VRL=4ΩPo=20W
85%＠VDDP=12.0VRL=8ΩPo=10W
・Lowdistortion(THD+N)
0.03%＠1kHzRL=4ΩPo=7W
・Highsignaltonoiseratio
100dB＠VDDP=12.0VInputsensitivity1.0VRL=4Ω
97dB＠VDDP=12.0VInputsensitivity150mVRL=4Ω
・Lowconsumptioncurrent(12V/5Vpowersupply)
WhenPowerMOSFET(FW332)isconnected.
30mA/7mA＠VDDP=12.0Vnosignal
0.1mA/7mA＠VDDP=12.0Vatmute
1μA/1μA＠VDDP=12.0Vatsleep
・CS(Channelseparation)
80dB＠1kHz
・Anygainsettingbyexternalresistors
・SleepfunctionbySLEEPterminal
・OutputmutefunctionbyMUTEterminal
・Overcurrentdetectionfunction
(Powersupplyshort-circuiting,Groundshortcircuiting,Loadshort-circuiting)
・Hightemperaturedetectionfunction
・Popnoisesuppressionfunctionatturn-onand
turn-off
・48-pinplasticLQFP(YDA135-VZ)
YDA135CATALOG
CATALOG No.:LSI-4DA135A2
2003.3
YDA135
Terminal configuration
PVSSL
N/C
HP_L
HN_L
LN_L
LP_L
LP_R
LN_R
HN_R
HP_R
N/C
PVSSR
36
35
34
33
32
31
30
29
28
27
26
25
YDA135-VZ
N/C
43
18
N/C
NFNL
44
17
NFNR
NFPL
45
16
NFPR
NFINL
46
15
NFINR
INL
47
14
INR
VDDL
48
13
VDDR
12
CDOR
N/C
19
11
42
VREFR
CDOL
10
CDIR
VSSR
20
9
41
TEST
CDIL
8
N/C
TPP
21
7
40
N/C
N/C
6
SENSEPR
PROT
22
5
39
SLEEP
SENSEPL
4
PVDDR
MUTE
23
3
38
VSSL
PVDDL
2
SENSENR
VREFL
24
1
37
N/C
SENSENL
<48 pin LQFP Top View>
2
YDA135
Terminal function
No.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
Name
N/C
VREFL
VSSL
MUTE
SLEEP
PROT
N/C
TPP
TEST
VSSR
VREFR
N/C
VDDR
INR
NFINR
NFPR
NFNR
N/C
CDOR
CDIR
N/C
SENSEPR
PVDDR
SENSENR
PVSSR
N/C
HP_R
HN_R
LN_R
LP_R
LP_L
LN_L
HN_L
HP_L
N/C
PVSSL
SENSENL
PVDDL
SENSEPL
N/C
CDIL
CDOL
N/C
NFNL
NFPL
NFINL
INL
VDDL
I/O
−
O
−
I
I
O
−
I
I
−
O
−
−
I
O
I
I
−
O
I
−
IH
−
IH
−
−
OH
OH
OH
OH
OH
OH
OH
OH
−
−
IH
−
IH
−
I
O
−
I
I
O
I
−
Function
Nonconnection
Lchannelreferencevoltageoutput
Groundfor5VpowersupplyofLchannel
Mutecontrol
Sleepcontrol
Warningsignaloutputfordetectionfunction
Nonconnection
Hightemperaturedetection
ICtest.ConnecttoVSSR
Groundfor5VpowersupplyofRchannel
Rchannelreferencevoltageoutput
Nonconnection
5VPowersupplyofRchannel
Rchannelanalogsignalinput
Rchannelinputgainsetting
Rchannelpositivesidefeedbackinput
Rchannelnegativesidefeedbackinput
Nonconnection
Rchannelofftimesetting(output)
Rchannelofftimesetting(input)
Nonconnection
Rchannelovercurrentdetection(PVDDside)
12VpowersupplyofRchannel
Rchannelovercurrentdetection(PVSSside)
Groundfor12VpowersupplyofRchannel
Nonconnection
RchannelpositivesidePMOSdriving
RchannelpositivesideNMOSdriving
RchannelnegativesideNMOSdriving
RchannelnegativesidePMOSdriving
LchannelnegativesidePMOSdriving
LchannelnegativesideNMOSdriving
LchannelpositivesideNMOSdriving
LchannelpositivesidePMOSdriving
Nonconnection
Groundfor12VpowersupplyofLchannel
Lchannelovercurrentdetection(PVSSside)
12VpowersupplyofLchannel
Lchannelovercurrentdetection(PVDDside)
Nonconnection
Lchannelofftimesetting(input)
Lchannelofftimesetting(output)
Nonconnection
Lchannelnegativesidefeedbackinput
Lchannelpositivesidefeedbackinput
Lchannelinputgainsetting
Lchannelanalogsignalinput
5VpowersupplyofLchannel
Note.I/O:5Vinput/5Voutput,IH/OH:12Vinput/12Voutput
3
YDA135
Internal block diagram
CDIL
41
NFINL
INL
VREFL
CDOL
42
45
34
46
47
Balanced
PulseWidth
Modulation
Unit
(Lchannel)
33
31
PVSSL
VDDL
VSSL
VDDR
VSSR
PVDDR
PVSSR
32
38
39
36
37
Overheat
Detection
48
3
13
10
OverCurrent
Detection
22
24
Power
Supply
Voltage
Detection
8
4
23
Control
Block
25
5
6
9
16
VREFR
INR
27
11
Balanced
PulseWidth
Modulation
Unit
(Rchannel)
14
28
30
29
NFINR
4
HP_L
HN_L
LP_L
2
44
PVDDL
NFPL
15
17
20
19
CDIR
CDOR
LN_L
NFNL
SENSEPL
SENSENL
SENSEPR
SENSENR
TPP
MUTE
SLEEP
PROT
TEST
NFPR
HP_R
HN_R
LP_R
LN_R
NFNR
YDA135
Description of terminal function
In the following explanations, "L" level and "H" level of SLEEP and MUTE terminals mean "VIL" and "VIH"
respectively, and "L" level and "H" level of PROT terminal mean "VOL" and "VOH" respectively.
"L" level and "H" level of output terminals such as HP_L and HN_L terminals also mean "VHOL" and "VHOH"
respectively.
Power supply and ground terminals
VDDL, VSSL, VDDR, VSSR (Pin No.48, 3, 13, 10)
VDDL and VSSL terminals are 5.0V power supply terminal and ground terminal for left channel signal processing
circuit respectively. VDDR and VSSR terminals are 5.0V power supply terminal and ground terminal for right
channel signal processing circuit respectively.
Left and right channels are equipped independent power supply terminal and ground terminal, respectirely.
All the ground terminals are connected through IC board (low resistor), but the power supply terminals for left and
right channels are separated from each other.
PVDDL, PVSSL, PVDDR, PVSSR (Pin No.38, 36, 23, 25)
PVDDL and PVSSL are 12 V power supply and ground terminals for left channel Power MOSFET driving circuit
respectively.
PVDDR and PVSSR are 12 V power supply and ground terminals for right channel Power MOSFET driving circuit
respectively.
Left and right channels are equipped independent power supply terminal and ground terminal, respectirely.
All the ground terminals are connected through IC board (low resistor), but the power supply terminals for left and
right channels are separated from each other.
Analog terminals
INL, NFINL, INR, NFINR (Pin No.47, 46, 14, 15)
INL and NFINL are analog signal input and gain adjustment terminals for left channel.
INR and NFINR are analog signal input and gain adjustment terminals for right channel.
The terminals are connected respectively to the negative input terminal and output terminal of the first stage
inversion operational amplifiers.
The amplifier gain is set by connecting an input resistor and a feedback resistor to both terminals as shown the
"Example of application circuit".
The use of this inversion operational amplifier allows making a filter such as low band boost filter.
VREFL, VREFR (Pin No.2, 11)
VREFL is the reference voltage output terminal for the left channel. It outputs 1/2 of 5V power supply terminal
(VDDL) voltage.
VREFR is the reference voltage output terminal for the right channel. It outputs 1/2 of 5V power supply terminal
(VDDR) voltage.
Connect a capacitor with capacitance necessary to stabilize the voltage. Refer to "Pop noise reduction functions".
NFPL, NFNL, NFPR, NFNR (Pin No.45, 44, 16, 17)
NFPL and NFNL are the digital amplifier feedback input terminals for left channel.
NFPR and NFNR are the digital amplifier feedback input terminals for right channel.
Connect the feedback signal of positive side and negative side of H-bridge configuration Power MOSFET output to
each terminal. At this time, as described in the "Example of application circuit", divide the voltage of feedback signal
with external resistor to prevent the maximum voltage from exceeding 5V and input to each terminal.
HP_L, HN_L, LP_L, LN_L, HP_R, HN_R, LP_R, LN_R (Pin No.34, 33, 31, 32, 27, 28, 30, 29)
HP_L, HN_L, LP_L and LN_L are Power MOSFET driving terminals for left channel.
HP_L is a driving output terminal for positive side P channel Power MOSFET (PMOS), HN_L is the one for positive
side N channel Power MOSFET (NMOS), LP_L is the one for negative side P channel Power MOSFET (PMOS),
and LN_L is the one for negative side N channel Power MOSFET (NMOS).
HP_R, HN_R, LP_R and LN_R are Power MOSFET driving terminals for right channel.
HP_R is a driving output terminal for positive side P channel Power MOSFET (PMOS), HN_R is the one for positive
side N channel Power MOSFET (NMOS), LP_R is the one for negative side P channel Power MOSFET (PMOS),
and LN_R is the one for negative side N channel Power MOSFET (NMOS).
5
YDA135
CDIL, CDOL, CDIR, CDOR (Pin No.41, 42, 20, 19)
CDIL and CDOL are for connecting a resistor and a capacitor for setting off time of external Power MOSFET for left
channel (refer to "Amplifier functions").
CDIR and CDOR are for connecting a resistor and a capacitor for setting off time of external Power MOSFET for
right channel.
It is necessary to determine the resistor and capacitor to obtain a time constant according the characteristics of
Power MOSFET that is to be used and distortion rate of amplifier you need. Refer to "Amplifier functions".
SENSEPL, SENSENL, SENSEPR, SENSENR (Pin No.39, 37, 22, 24)
SENSEPL and SENSENL are the overcurrent detection terminals for left channel.
SENSEPR and SENSENR are the overcurrent detection terminals for right channel.
As described in the "Example of application circuit", connect an end of the current detection resistor to power supply
side and ground side of Power MOSFET, and connect other end of the resistor to SENSEPL and SENSENL
terminals, and SENSEPR and SENSENR terminals respectively.
This IC determines that overcurrent state has occurred when the voltage drop at the current detection resistor
becomes specified values (VOCPN and VDDP-VOCPP) or over.
It is necessary to determine the resistance of the current detection resistor optimally according to the characteristics
of Power MOSFET.
When the overcurrent detection circuitry of left channel or right channel determines overcurrent state, "H" level is
outputted from the warning signal output (PROT) terminal.
When the warning signal is outputted due to overcurrent detection, this IC keeps the warning signal output
(PROT="H" level) after the current return to normal state.
TPP (Pin No.8)
TPP is the high temperature detection terminal.
As described in the "Example of application circuit", connect a temperature detection element (such as a posistor)
between TPP terminal and 5 V system ground terminal. In addition, connect a resistor with proper value between
TPP terminal and 5V system power supply terminal. At this time, arranges the temperature detection near Power
MOSFET. As the temperature of Power MOSFET rises, the resistor value of the temperature detection element
increases, and the voltage of TPP terminal also increases accordingly. This IC determines that high temperature
state has occurred when the voltage of TPP terminal has become specified value (VTPP) or over, and outputs "H"
level from the warning signal output (PROT) terminal.
When the warning signal is outputted due to high temperature detection, this IC keeps the warning signal output
(PROT="H" level) after the temperature return to normal state.
Digital terminals
SLEEP (Pin No.5)
SLEEP is the sleep control terminal. It controls both left and right channels simultaneously.
When SLEEP terminal is set at "H" level, all functions of this IC is stopped, and this IC is placed in the sleep state.
At this time, all Power MOSFET driving terminals output signals that turn off the Power MOSFETs.
Though all Power MOSFETs are placed in the off state (non conductive state), the speaker terminal is made ground
potential by the externally connected resistor.
At this time, restrain the power consumption at the minimum, and warning signal (PROT terminal output) is set at
"L" level.When SLEEP terminal is changed from "H" level to "L" level, this IC goes into normal operation after
sufficient time (starting time) to make each reference voltage reaches a fixed potential.
MUTE (Pin No.4)
MUTE is the mute control terminal. It controls both left and right channels simultaneously.
When MUTE terminal is set at "H" level, all Power MOSFET driving terminals output signals that turns off the Power
MOSFETs. Though all Power MOSFETs are placed in the off state (non conductive state), the speaker terminal is
made ground potential by the externally connected resistor, and the amplifier becomes mute state. At this time, the
overcurrent protection function stops.
When MUTE terminal is set to "L" level, this IC goes into normal operating state.
6
YDA135
PROT (Pin No.6)
PROT is the warning signal output terminal that has both overcurrent and high temperature detection functions.
The terminal outputs "H" level when either function detects an abnormality state.
When the warning signal (PROT terminal="H" level) is outputted by abnormality state detection, this IC keep the
warning signal output after return to normal state.
The warning signal is cancelled by changing the state of SLEEP terminal to "H" level or turning off the power supply.
TEST (Pin No.9)
This is the terminal for testing. Connect to VSSR terminal.
Mode setting and error detection
Rchannel
SLEEP
MUTE
TPP
SENSPL
SENSNL
HP_L
HN_L
LP_L
LN_L
HMOS_L
LMOS_L
SENSPR
SENSNR
HP_R
HN_R
LP_R
LN_R
HMOS_R
LMOS_R
PROT
Lchannel
H
L
L
L
L
L
L
L
L
＊
H
H
L
L
L
L
L
L
＊
P
F
P
F
P
P
P
P
＊
＊
＊
P
P
F
P
P
P
＊
＊
＊
P
P
P
F
P
P
H
H
H
X
X
X
X
X
X
L
L
L
X
X
X
X
X
X
H
H
H
X
X
X
X
X
X
L
L
L
X
X
X
X
X
X
L
L
L
X
X
X
X
X
X
L
L
L
X
X
X
X
X
X
＊
＊
＊
P
P
P
P
F
P
＊
＊
＊
P
P
P
P
P
F
H
H
H
X
X
X
X
X
X
L
L
L
X
X
X
X
X
X
H
H
H
X
X
X
X
X
X
L
L
L
X
X
X
X
X
X
L
L
L
X
X
X
X
X
X
L
L
L
X
X
X
X
X
X
L
X
H
X
H
H
H
H
H
Mode
Sleepmode
Mutemode
Mutemode/Hightemperaturedetection
2channeloutputmode
2channeloutputmode/Hightemperaturedetection
2channeloutputmode/Lchannelovercurrentdetection
2channeloutputmode/Lchannelovercurrentdetection
2channeloutputmode/Rchannelovercurrentdetection
2channeloutputmode/Rchannelovercurrentdetection
Note:
1) HMOS_L, LMOS_L, HMOS_R and LMOS_R terminal mean outputs of Power MOSFET that are positive at left
channel side, negative at left channel side, positive at right channel side, and negative at right channel side
respectively.
"L" means that the terminals are pulled down by the resistor that is used in the "Example of application circuit".
"X" means pulse outputting state.
2) "X" of PROT terminal means that is in state of either "L" or "H" by the previous state.
3) "P" of SENSE* and TPP terminals means normal state (Pass), and "F" means abnormal state (Fail).
4) "X" of output terminals such as HP_L, HN_L terminals means pulse outputting state.
5) "*" means "Don't care".
7
YDA135
Description of functions
Amplifier functions
CD
RD
CDIL/
CDIR
CDOL/
CDOR
PVDD
YDA135
INL/
INR
RNP
RNP
VREFL/
VREFR
Balanced
PulseWidth
Modulation
Unit
(Lchannel/
Rchannel)
CREF
LO
HP_L/
HP_R
CO
HN_L/
HN_R
LP_L/
LP_R
CO
RL
LN_L/
LN_R
SENSENL/
SENSENR
Firststage
operational
amplifier
section
Digital
amplifier
section
NFNL/
NFNR
RS
RNFH
LO
RNFL
RI
RNFH
SENSEPL/
SENSEPR
RFB
RNFL
NFPL/ RS
NFPR
NFINL/
NFINR
PVSS
Amplifier functions block diagram
The amplifier section of this IC consists of the first stage operational amplifier and the second digital amplifier.
The gain of the first stage operational amplifier is set with externally connecting an input resistor (RI) and feedback
resistor (RFB). The second stage digital amplifier connects Power MOSFET externally, of which output is fed back to
the modulation circuitry of the digital amplifier section through the external feedback resistors (RNFH and RNFL).
This feature realizes the low distortion rate.
To prevent occurrence of penetration current caused by simultaneous on state of external Power MOSFET, a period
in which both PMOS and NMOS are not on state ("off time") is provided. This time is set by using an external
resistor (RD) and capacitor (CD).
The output of Power MOSFET is connected to the speakers through the secondary low pass filter consisting of an
inductor (Lo) and a capacitor (Co). This feature removes the carrier frequency component contained in the output of
Power MOSFET, and sent only audio signals to the speakers.
Gain setting
The gain of first stage operational amplifier is calculated by the following formula. The gain of the digital amplifier
section that includes the gain (8dB) of internal digital amplifier section and gain of the external feedback resistor is
calculated by the following formula.
Gain
First stage operational amplifier section 20*log(2*RFB/RI) dB (GainissetbyRI andRFB.Condition:RI>2kΩ)
Digital amplifier section
8+20*log(1+RNFH/RNFL) dB
8
YDA135
An "Example of application circuit" uses RI=8.2kΩ, RFB=39kΩ, RNFH=3.3kΩ and RNFL=2.4kΩ, which give total
gain (Av) that is calculated by using the following formula. With this setting, the input sensitivity is 150mVrms, where
the maximum output can be obtained when the input is 150mVrms.
Av (dB) = 20*log(2*39/8.2) + 8 + 20*log(1+3.3/2.4)
= 35.1 dB
This section explains how to set the gain for maximum level of the input signal. The relationship between the
maximum level of input signal, Vin (peak value), RI and RFB is given by the following formula. (When RNFH=3.3kΩ,
RNFL=2.4kΩ.)
Vin(peak value) = RI / RFB
For example, when setting as Vin = 300mVrms, the formula is ”300mVrms* √2 = RI / RFB”. When RFB = 39kΩ,
the value of RI is approximately 16kΩ. Set the value of RI as 2kΩ or less.
When setting the gain of the operational amplifier, which is initial stage, it is necessary to observe the restrictions
that are described in “Pop noise reduction functions”. Due to the limitation on operational amplifier driving
capability, it is necessary to make the feedback resistance (RFB) 10kΩ or over.
The use of the initial stage operational amplifier section allows configuration of a “Low band boost filter circuit”
described below.
This filter has a frequency response which is similar to the “Characteristics of low band boost filter” described
below, and the amount of boost (Gv) for the gain of initial stage inversion operational amplifier, and the cut-off
frequency (fb) at a point where the boost gain is reduced by 3dB can be described by the following formula.
CFB
22pF
CB
RFB
CI
RI
Lch(Rch)
10μF
NFINL(NFINR)
39kΩ
RB
8.2kΩ
INL(INR)
Low band boost filter circuit
Gain(dB)
-3dB
Gainof
firststage
operational
amplifier
(RFB/RI)
Gv
fb
Characteristicsoflowbandboostfilter
Frequency(Hz)
Gv(dB) = 20*log((RFB + RB)/RFB )
fb(Hz) = 1/(2π*CB*RB)
When low band boost function is used, the total gain in the low band that is boosted after it is amplified by the
digital amplifier section becomes “total gain (Av) + boost amount (Gv)".
For the "Example of application circuit", a capacitor (CFB) for cutting off high frequency range is attached for
limiting the band of input signal. The value can be adjusted if necessary. (Cut-off frequency = 1/(2π*CFB*RFB)).
DC cutting capacitor (CI) is attached for limiting the input DC current. This capacitor and input resistor (RI)
constitutes a low cutoff filter. Set the filter for sufficiently low cutoff frequency. (Cut-off frequency = 1/(2π*CI*RI)).
The external feedback resistors (RNFH and RNFL) are set so that they meet the following relational expression
depending on the input stage power supply voltage (VDD) and output stage power supply voltage (PVDD). For
RNFL, select the largest value resistor meeting this expression.
Use the resistor with an accuracy of 1％ for reduction of offset voltage.
RNFL≦VDD/(VDDP-VDD)*RNFH
600Ω≦(RNFH+RNFL)≦6kΩ
9
YDA135
Selection of Power MOSFET
Power MOSFET can be selected on the user side within the range of the absolute maximum rating.
When selecting Power MOSFET, take note of the following matters.
・The drain side voltage may be twice the maximum power supply voltage due to the counter electromotive force
developed in the inductive load.
When VDDP=12V, use Power MOSFET of which withstand voltage VDS is 30V or higher.
・For the gate voltage, the voltage VDDP is applied. Therefore, use Power MOSFET of which withstand voltage VGS
is 20V or higher.
・Due to the limitation of allowable power consumption of this IC, use Power MOSFET of which total input charges
(VDS=10V, VGS=10V) is 9 nC or less.
To prevent destruction of Power MOSFET caused by simultaneous turn-on of PMOS and NMOS of Power MOSFET,
off time such as the following "Power MOSFET output waveform and off time" can be set for Power MOSFET
depending on the resistor (RD) and capacitor (CD) that are connected to CDIL, CDIR, CDOL and CDOR terminals.
Connect a proper resistor (RD) and capacitor (CD) according the characteristics of Power MOSFET.
As the time constant is made smaller, off time becomes shorter. Adjust the off time so that the penetration current
does not flow through the Power MOSFET, as shorter off time can cause penetration current to flow.
As the time constant is made larger, off time becomes longer. Longer off time makes the margin from the moment of
simultaneous turn on of the Power MOSFET larger, but at the same time, the distortion characteristic changes for the
worse.
Off time
Off time
HP_L(HP_R)
LP_L(LP_R)
HN_L(HN_R)
LN_L(LN_R)
Off time
Off time
Power MOSFET output waveform and off time
An indication of off time is in the range approximately from 10ns to 40ns. As an example, the relationship between
the resistance (RD) and off time is as described by the “Relationship between off time and resistance (RD)”
described below when the capacitance (CD) = 15pF.
Relationship between off time and resistance (RD) : (CD=15pF)
Off time(ns)
40.0
30.0
20.0
10.0
0.0
0
1
2
3
4
5
resistance(RD)(kΩ)
Selection of inductor for output filter
The cutoff frequency (fc) of the LC low pass filter that is connected to the output of the Power MOSFET can be
obtained by using the following formula.
To obtain an ideal frequency response, set the Q value of LCR resonance circuit to approximately 0.7.
fc(Hz)=1/(2*π*√(Lo*Co))
Q=1/RL*√(Lo/Co)=0.7
Typically, the one with the following value is used depending on the speaker impedance assuming that the cutoff
frequecy of 50kHz is used.
RL(Load impedance)
Lo(Inductance)
Co(Capacitor)
4Ω
10μH
1μF
8Ω
22μH
0.47μF
16Ω
39μH
0.27μF
The distortion factor and voice quality may be affected by the type of coil to be used. Select the best suited one
according to the response required.
10
YDA135
Overcurrent detection functions
The overcurrent detection is a function that determines that the overcurrent state has occurred and set PROT
terminal to "H" level, when the current flowing in the external Power MOSFET has become equal to or higher than
the specified value. (This IC does not internally perform processing that turns off Power MOSFET automatically in
such case.)
For the "Example of application circuit", the circuit related to the overcurrent detection function is as shown in the
following figure, "Overcurrent detection function block diagram".
Connect a current detection resistor (RS) between PMOS (source side) pin and power supply pin PVDD of Power
MOSFET, and between NMOS (source side) pin and PVSS pin. Connect PMOS (source side) pin and SENSEPL
pin through the low pass filter consisting of RSNS and CSNS, and NMOS (source side) and SENSENL pins as well.
To prevent erroneous detection of glitch noise that can occur at switching of Power MOSFET, be sure to use the
low pass filter consisting of RSNS and CSNS. Connect SENSEPR pin and SENSENR pin in the same way.
This IC recognizes an overcurrent state when the potential of SENSEPL pin or SENSEPR pin has decreased below
the overcurrent detection threshold voltage (VOCPP) for a certain period (TOCP), bringing PROT pin to "H" level.
When the potential of SENSENL pin or SENSENR pin has increased over the overcurrent detection threshold
voltage (VOCPN) for a certain period, it recognizes the overcurrent state, bringing PROT pin to "H" level. At this
time, set SLEEP pin of MUTE pin to "H" to force the Power MOSFET to OFF.
After this, inputting "H" level once to SLEEP or turning off the power supply and then on again can restore the
output of PROT pin to initial "L" state.
When it is not necessary to use the overcurrent detection function, connect SENSEPL pin and SENSEPR to PVDD,
and SENSENL pin and SENSENR pin to PVSS (to disable the function).
When in sleep mode (SLEEP pin = "H" level) or in mute mode (MUTE pin = "H" level), this IC sets the Power
MOSFET to OFF state, and thus, the overcurrent detection function of both L channel and R channel are stopped.
For this circuit, use the overcurrent detection resistor (RS) with low inductive component. The resistance is to be
determined based on the drain current rating (IDMAX: pulse current) and overcurrent threshold voltages (VOCPP,
VOCPN) according to the conditions described below.
RS ≧ VOCPN / IDMAX
PVDD
PVDD
YDA135
OverCurrent
Detection
CSNS
PVDD
RS
VDDP-VOCPP
SENSEPL/
SENSEPR
RSNS
HP_L/
HP_R
PROT
Q
S
Thermal Detection
HN_L/
HN_R
LP_L/
LP_R
SR-FF
R
LN_L/
LN_R
OverCurrent
Detection
SLEEP
SENSENL/
SENSENR
Power
on
Reset
RSNS
VOCPN
CSNS
RS
PVSS
PVSS
PVSS
Overcurrent detection function block diagram
11
YDA135
When overcurrent has been detected, Power MOSFET can be protected by the following methods.
(1)Turning off Power MOSFET when overcurrent has been detected.
Connect PROT terminal and MUTE terminal externally as shown in the following "Power MOSFET protection
circuit". With this method, the device is brought into mute state when overcurrent has been detected, where
Power MOSFET is turned off to limit the current flowing into Power MOSFET. At this time, the protected state
can be cancelled by setting SLEEP terminal to "H" level or by bringing VDD or PVDD power supply terminal
voltage to the level below the shut off voltage once.
(2)Turning off Power MOSFET when overcurrent has been detected and restarting it.
Connect PROT terminal and SLEEP terminal through external circuit as shown in the following "External
automatic restoration circuit". With this method, SLEEP terminal becomes "H" level when overcurrent has been
detected, and this IC is brought into sleep state (Power MOSFET is turned off). After this, when a certain period
that depends on the RC time constant has elapsed, SLEEP terminal becomes "L" level where this IC restarts
automatically.
PROT
MUTE
PROT
S
Q
SLEEP
SR-FF
R
YDA135
Power MOSFET protection circuit
YDA135
External automatic restoration circuit
High temperature detection functions
The high temperature detection is a function that determines that the high temperature state has occurred and set
PROT terminal to "H" level when the temperature of the temperature detection element (such as posistor*1) that is
placed in the location that is thermally equivalent with Power MOSFET has become equal to or higher than the
specified value. (This IC does not internally perform processing that turns off Power MOSFET automatically in such
case.)
For the "Example of application circuit", the circuit related to the high temperature detection function is as shown in
the next page, "High temperature detection function block diagram".
*1: "posistor" is a registered trade mark of Murata Manufacturing Co., Ltd. for their positive thermisters.
12
YDA135
VDD
VDD
YDA135
RTP
PVDD
RS
TPP
PROT
Q
S
HP_L/
HP_R
SR-FF
R
HN_L/
HN_R
LP_L/
LP_R
1/2VDD
SLEEP
OverTemperature
Detection
LN_L/
LN_R
Power
on
Reset
RS
VSS
VSS
PVSS
High temperature detection function block diagram
Connect the temperature detection element with positive temperature coefficient between VSS and TPP terminal by
the number of pieces required.
In addition, connect a resistor(RTP) between TPP terminal and VDD power supply terminal. Resistor value of
temperature detection element is changed by rise in temperature. Select a resistor so that the threshold (VTPP) is
attained depending on the characteristic of the temperature detection element.
This IC determines that high temperature state has occurred when the potential of TPP terminal has exceeded the
high temperature detection threshold voltage (VTPP) for a certain period (TTPP), and then sets PROT terminal to "H"
level. At this time, set SLEEP terminal or MUTE terminal to "H" level to turn off Power MOSFET forcibly to limit the
temperature rise.
PROT terminal output can be returned to initial "L" level output state by inputting "H" level once to SLEEP terminal
or by turning off the power and then on again.
In sleep mode (SLEEP="H"), the high temperature detection function of this IC is disabled.
Since TPP terminal is a single terminal, the temperature detection circuit detects temperature of two channels
collectively outside of this IC.
When the high temperature detection function is not used, connet TPP to the ground (to disable the high
temperature detection function).
When high temperature state has been detected, Power MOSFET can be protected by the following methods.
(1)Turning off Power MOSFET when high temperature has been detected.
Connect PROT terminal and MUTE terminal externally as shown in the "Power MOSFET protection circuit" of the
previous page. With this method, the device is brought into mute state when high temperature has been detected,
where Power MOSFET is turned off to limit the current flowing into Power MOSFET to allow reduction of the
temperature. At this time, the protected state can be cancelled by setting SLEEP terminal to "H" level once or by
bringing VDD or PVDD power supply terminal voltage to the level below the shut off voltage once.
(2)Turning off Power MOSFET when high temperature has been detected and restarting it after a certain period.
Connect PROT terminal and SLEEP terminal through external circuit as shown in the "External automatic
restoration circuit" of the previous page.
With this method, SLEEP terminal becomes "H" level when high temperature has been detected, and this IC is
brought into sleep state (Power MOSFET is turned off). After this, when a certain period that depends on the RC
time constant has elapsed, SLEEP terminal becomes "L" level where this IC restarts automatically.
13
YDA135
Sleep control functions
When SLEEP terminal is set to H" level, this IC changes into sleep mode. When SLEEP terminal is set to "L" level,
this IC changes into normal operating state. In sleep mode, all functions are disabled, and power consumption is
minimized.
At this time, all Power MOSFET driving terminals output signals that turns off the Power MOSFETs. Though all
Power MOSFETs become off state, the speaker terminal is made ground potential by the externally connected
resistors (RNFL and RNFH).
When MUTE terminal is changed from "H" level to "L" level, restarting sequence operates internally. This IC
changes into normal operating state after the period that is set with a capacitor connected to VREFL terminal and
VREFR terminal (starting time) has elapsed.
When SLEEP terminal is set to "H" level, PROT terminal is set to "L" level forcibly.
Output mute control functions
When MUTE terminal is set to H" level, this IC change into mute mode. When MUTE terminal is set to "L" level, this
IC change into normal operating state. In the mute mode, the internal clock stops. At this time, all Power MOSFET
driving terminals output signals that turns off the Power MOSFETs. Though all Power MOSFETs become off state,
the speaker terminal is made ground potential by the externally connected resistors (RNFL and RNFH).
Pop noise reduction functions
This IC includes pop noise reduction function that works when turn on and turn off the power supply and enabling
or canceling sleep mode.
At power on, this IC starts the starting sequence after 12V system's power supply voltage (VDDP) for Power
MOSFET driving circuit and 5 V system's power supply voltage (VDD) for signal processing circuit has exceeded
their low voltage malfunction prevention threshold (VUV12 and VUV5) respectively. In the starting sequence, the pop
noise can be reduced because the mute mode is canceled after the potential of input signal terminals (INL and
INR) and potential of reference voltage output terminals (VREFL and VREFR) have stabilized sufficiently (after the
elapse of starting period).
Also, when shutting off the power supply, the pop noise can be reduced by reducing 12V power supply voltage and
5V power supply voltage below the low voltage malfunction prevention threshold (VUV12 and VUV5) earlier than the
shift of the potential of input signal terminals (INL and INR) and potential of reference voltage output terminals
(VREFL and VREFR).
The pop noise is also reduced by enabling the mute mode when the 5V system power supply voltage has changed
10% of 1/2 of VREF terminal voltage. Moreover, the pop noise can be reduced by using MUTE terminal control
circuit as shown in the "Example of application circuit" when the speed of reduction of the power supply voltage is
slow.
When the sleep mode is disabled, the pop noise can be reduced by using the starting sequence.
When the sleep mode is enabled, the pop noise is reduced because the mute mode is enabled simultaneously.
To make the pop noise reduction function operate effectively when turning on the power supply, it is necessary to
set the values of capacitor (CREF) that is connected to VREFL terminal and VREFR terminal, the resistor (RI) and
capacitor (CI) that are connected to INL terminal and INR terminal as described below.
CREF > RI * CI / 5000
Pop noise reduction functions
Starting time is a period for each reference voltage to reach the specified potential (for charging capacitors (CREF)
of VREFL and VREFR terminals) when the power supply is turned on or is turned on again. This period varies in
relation to the capacitance (CREF) of VREFL and VREFR terminals. The table of starting time is as follows:
CREF capacitor(µF)
2
10
30
50
Starting time (sec)
0.13
0.33
0.85
1.40
How to supply power to 5V system
Since the operation of the 5V system power supply of this IC is guaranteed in the wide fluctuation range (10%), the
power can be generated from 12V system power supply by using a zener diode. This features allows to operate
this IC by using only a 12V power supply.
14
YDA135
Monaural operation
This IC can be operated in monaural mode by modifying the "Example of application circuit" as follows.
At this time, left channel is to be used.
It is not necessary to connect the resistors and capacitors, Power MOSFET and filter coils for right channel.
Terminal treatment in monaural operation
Pin No.
Name
Terminal treatment
10
VSSR
Connect to ground
11
VREFR
Non connection
13
VDDR
Connect to 5V power supply
14
INR
Connect to 47Pin INL
15
NFINR
Non connection
16
NFPR
Connect to 5V power supply
17
NFNR
Connect to ground
19
CDOR
Connect to 20Pin CDIR
20
CDIR
Connect to 19Pin CDOR
22
SENSEPR
Connect to 12V power supply
23
PVDDR
Connect to 12V power supply
24
SENSENR
Connect to ground
25
PVSSR
Connect to ground
27
Non connection
HP_R
28
Non connection
HN_R
29
Non connection
LN_R
Non connection
30
LP_R
15
YDA135
Example of application circuit
RPN2
RPN1
12V
RD
6.8kΩ 5.1kΩ
CD
QP
5V
SLEEP
PROT
RPN3
4.7kΩ
CFB
MUTE
TEST
CDOL
CDIL
Control
Block
RI
8.2kΩ
SENSEPL
Over
Current
Detection
INL
5V
1μF
VDDR
1μF
VSSR
12V
PVDDL
RP4
1Ω
1μF
NFNL
Power
Supply
Voltage
Detection
RP4
1Ω
SENSEPR
Over
Current
Detection
CFB 22pF
RI
8.2kΩ
LN_R
SENSENR
TPP
10kΩ
RTP Posistor
16
CDIR
CD
RD
CDOR
100kΩ RSNS
1kΩ
NFNR
12V
RS
50mΩ
RNFH
3.3kΩ
LO
10μH
RPD
100kΩ
CO
1μF
CO
1μF
LP_R
Overheat
Protection
5V
12V
180pF
12V
RPU
100kΩ
Over
Current
Detection
VREFR
CREF
33μF
RNFL
2.4kΩ
HP_R
HN_R
Balanced
PulseWidth
Modulation
Unit
(Rchannel)
INR
RNFH
3.3kΩ
CSNS
180pF
12V
RPU
CP4
0.1μF PVSSR
RFB
39kΩ
RS
50mΩ
RSNS
1kΩ
CSNS
PVDDR
NFINR
RL
LO
10μH
NFPR
12V
CI
10μF
CO
1μF
RNFL
2.4kΩ
CP4
0.1μF PVSSL
1μF
CO
1μF
RPD
100kΩ
SENSENL
VSSL
5V
RPD
100kΩ
LP_L
LN_L
RNFH
3.3kΩ
LO
10μH
12V
RPU
100kΩ
Over
Current
Detection
VDDL
12V
RS
50mΩ
100kΩ RSNS
1kΩ
HP_L
HN_L
Balanced
PulseWidth
Modulation
Unit
(Lchannel)
VREFL
CREF
33μF
180pF
12V
RPU
NFINL
RFB
39kΩ
12V
CSNS
22pF
CI
10μF
RNFL
2.4kΩ
NFPL
RPD
100kΩ
RL
LO
10μH
RSNS
1kΩ
RS
50mΩ
RNFH
3.3kΩ
CSNS
180pF
RNFL
2.4kΩ
YDA135
Electrical characteristics
1. Absolute maximum rating
Item
Symbol
Unit
Min.
Max.
VDDP
-0.3
14.0
V
Power supply voltage for 12V system (PVDD) *1,*2, *3
Power supply voltage for 5V system (VDD) *1, *2, *4
VDD
-0.3
7.0
V
Input and output voltage for 12V system *5
VINP
V
VDDP+0.5
-0.5
Input and output voltage for 5V system *6
VIN
V
VDD+0.5
-0.5
Storage temperature
TSTG
-50
125
℃
Note: The absolute maximum rating is a value that must not be exceeded to guarantee the reliability and life of
this IC, and thus, the use of this IC over the rating even for a moment may break down the device
immediately or deteriorate its reliability severely.
*1: VSS covers all ground terminals including VSS, VSSL, VSSR, PVSSL and PVSSR. Place all VSS
terminals in the same potential.
*2: The voltage is referenced to VSS=0V.
*3: 12V system power supply terminal (PVDD) covers PVDDL and PVDDR terminals.
*4: 5V system power supply terminal (VDD) covers VDDL and VDDR terminals.
*5: 12V system input/output terminal covers SENSENL, SENSEPL, SENSENR, SENSEPR, HP_L, HN_L,
LP_L, LN_L, HP_R, HN_R, LP_R and LN_R terminals.
*6: 5V system input/output terminal covers SLEEP, MUTE, PROT, TPP, INL, NFINL, VREFL, NFPL, NFNL,
CDIL, CDOL, INR, NFINR, VREFR, NFPR, NFNR, CDIR and CDOR terminals.
2. Recommended operating conditions
Symbol
Item
Min.
Typ.
Max.
Unit
Power supply voltage for 12V system *1
9.0
12.0
13.5
V
PVDD
Power supply voltage for 5V system *2
4.5
5.0
5.5
V
VDD
Operating ambient temperature( ambient temperatureTa)
TOP
0
25
70
℃
Note: When this IC is used outside of the above voltage range may lead to malfunction of the IC, possibly causing
generation of noise on the speakers.
*1: The voltage is referenced to VSS=0V.
3.DC characteristics (VSS=0V, VDD=5V±0.5V, VDDP=9V〜13.5V, Ta=0℃〜70℃）
Item
Symbol Condition
Min.
Typ.
Max.
HP_L,HN_L,LP_L,LN_L,HP_R,HN_R,
VHOH IOH=-10mA VDDP-0.4
LP_R,LN_R output voltage "H" level
HP_L,HN_L,LP_L,LN_L,HP_R,HN_R,
VHOL IOL=10mA
0.4
LP_R,LN_R output voltage "L" level
PROT output voltage "H" level
VOH
IOH=-80μA VDD-1.0
PROT output voltage "L" level
VOL
0.4
IOL=1.6mA
SLEEP, MUTE input voltage "H" level
VIH
0.7*VDD
SLEEP, MUTE input voltage "L" level
VIL
0.3*VDD
Power supply side overcurrent detection threshold voltage *1 VOCPP
VDDP-0.5
Ground side overcurrent detection threshold voltage *2
VOCPN
0.5
Overcurrent detection delay time
TOCP
0.4
High temperature detection threshold voltage
VTPP
1/2*VDD
High temperature detection delay time
TTPP
0.4
12V power supply side threshold voltage prevention
5.0
VUV12
of low voltage malfunction
5V power supply side threshold voltage prevention
3.5
VUV5
of low voltage malfunction
1
Consumption current (sleep mode)
VDD
ISLEEP
PVDD
1
7
Consumption current (mute mode)
VDD
IMUTE
PVDD
0.1
7
Consumption current (2 channel output mode) VDD
IDD
PVDD
30
(no signal, no filter)
Note: *1: PVDD side overcurrent detection terminal covers SENSEPL, SENSEPR terminals.
*2: PVSS side overcurrent detection terminal covers SENSENL, SENSENR terminals.
Unit
V
V
V
V
V
V
V
V
μs
V
μs
V
V
μA
μA
mA
mA
mA
mA
17
YDA135
4. Analog characteristics (VSS=0V, VDD=5.0V, VDDP=12.0V, Ta=25℃, load impedance=4Ω, Frequency=1kHz）
Item
Symbol
Condition
Min.
Typ.
Max.
Unit
PO
Maximum output
THD=0.1％
W
13
THD=1％
14
W
THD=10％
20
W
Voltage gain
AV
35.1
dB
(RI=8.2kΩ, RFB=39kΩ)
Total harmonic distortion
THD+N Po=7W
0.03
％
(Band Width: 20kHz )
SNR
Signal/noise ratio(A-Filter,
Input sensitivity 150mV
97
dB
Band Width: 20kHz, Po=20W)
Input sensitivity 1.0V
100
dB
CS
Channel separation
80
dB
85
Maximum efficiency
Load impedance=8Ω
η
％
80
Load impedance=4Ω
％
30
VO
mV
Output offset voltage
Note: All analog characteristics shown above are the values obtained on the Yamaha's evaluation environment.
The characteristics may vary according to the Power MOSFET, coils, capacitors and pattern layout that are
used in the system.
18
YDA135
Characteristics example
THD+N / Input frequency
Input signal frequency (Hz)
Efficiency (%)
Efficiency / Power
19
YDA135
Power / PVDD power supply terminal voltage
Channel separation (dB)
4Ω
8Ω
Channel separation / signal frequency
Signal frequency (Hz)
PVDD power supply terminal voltage (V)
PSRR (PVDD power supply)
PSRR (VDD power supply)
Power supply rejection ratio frequency (Hz)
Power supply rejection ratio frequency (Hz)
Frequency characteristics
6
Noise level (dB)
3
Gain (dB)
0
-3
-6
-9
-12
10
FFT frequency (Hz)
Total Gain 35dB (Input sensitivity=150mV)
20
100
1000
Frequency (Hz)
10000
100000
YDA135
External dimensions of package
YDA135-VZ
C-PK48VP-0
12.00±0.40
10.00±0.30
25
24
48
13
10.00±0.30
37
1
1.70 MAX. (取り付け高さ)
(Installation height)
0 MIN. (STAND OFF)
P-0.65 TYP.
12.00±0.40
36
12
0.32 or 0.30
(1.00)
0-10°
端子厚さ：0.15 TYP. or 0.17 TYP.
(LEAD THICKNESS)
0.50
モールドコーナー形状は、本図面と
若干異なるタイプもあります。
カッコ内の寸法値は参考値とする。
モールド外形寸法はバリを含まない。
単位(UNIT) : mm(millimeters)
The shape of the molded corner
may slightly different from the
shape in this diagram.
The figure in the parenthesis ( )
should be used as a reference.
Plastic body dimensions do not
include burr of resin.
UNIT: mm
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21
YDA135
IMPORTANT NOTICE
1. Yamaha reserves the right to make changes to its Products and to this document without
notice. The information contained in this document has been carefully checked and is believed to
be reliable. However, Yamaha assumes no responsibilities for inaccuracies and makes no
commitment to update or to keep current the information contained in this document.
2. These Yamaha Products are designed only for commercial and normal industrial applications,
and are not suitable for other uses, such as medical life support equipment, nuclear facilities,
critical care equipment or any other application the failure of which could lead to death, personal
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3. YAMAHA ASSUMES NO LIABILITY FOR INCIDENTAL, CONSEQUENTIAL, OR SPECIAL
DAMAGES OR INJURY THAT MAY RESULT FROM MISAPPLICATION OR IMPROPER USE
OR OPERATION OF THE PRODUCTS.
4. YAMAHA MAKES NO WARRANTY OR REPRESENTATION THAT THE PRODUCTS ARE
SUBJECT TO INTELLECTUAL PROPERTY LICENSE FROM YAMAHA OR ANY THIRD
PARTY, AND YAMAHA MAKES NO WARRANTY OR REPRESENTATION OF NONINFRANGIMENT WITH RESPECT TO THE PRODUCTS. YAMAHA SPECIALLY EXCLUDES
ANY LIABILITY TO THE CUSTOMER OR ANY THIRD PARTY ARISING FROM OR RELATED
TO THE PRODUCTS' INFRINGEMENT OF ANY THIRD PARTY'S INTELLECTUAL PROPERTY
RIGHTS, INCLUDING THE PATENT, COPYRIGHT, TRADEMARK OR TRADE SECRET
RIGHTS OF ANY THIRD PARTY.
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CHARACTERISTICS AND PERFORMANCE OF YAMAHA PRODUCTS. YAMAHA ASSUMES
NO RESPONSIBILITY FOR ANY INTELLECTUAL PROPERTY CLAIMS OR OTHER
PROBLEMS THAT MAY RESULT FROM APPLICATIONS BASED ON THE EXAMPLES
DESCRIBED HEREIN. YAMAHA MAKES NO WARRANTY WITH RESPECT TO THE
PRODUCTS, EXPRESS OR IMPLIED, INCLUDING, BUT NOT LIMITED TO THE
WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR USE AND TITLE.
Note) The specifications of this product are subject to change without notice.
Agency
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Head Office 203, Matsunokijima, Toyooka-mura,
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Tel. +81-6-6252-6221
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C
2003 YAMAHA CORPORATION
Printed in Japan