Description

The CXA2020M/S, is a bipolar IC designed as

EIAJ TV sound multiplexing decoder, provides
various functions including sound multiplexing
demodulation, broadcast mode identification
(stereo/bilingual discrimination display), mode
display, and muting.

Features
· Adjustment free of filter.
· High frequency stereo separation improved.
· An internal active filter greatly reduces the external

parts.

· Use of the countdown method for broadcast mode

identification eliminates the necessity of adjusting
the identification system (Cue oscillator).

· Output level: 520mVrms (1kHz, monaural, 100%).
· Internal filter eliminates interference from digital

facsimile signals.

· The discrimination time needed to shift from

multiplexing sound to monaural sound is reduced.

· Forced monaural mode can be set to operate only

for stereo broadcasts or for stereo/bilingual
broadcasts.

Applications
· Color TVs
· Hi-Fi VCRs

Structure

Bipolar silicon monolithic IC

Pin Configuration

Absolute Maximum Ratings (Ta = 25°C)

[ ( ) is the pin No. for the CXA2020S.]

· Supply voltage

· Input signal (Pin 6)

Vis

0.6

Vp-p

· Control voltage

(Pins 5, 12, 13, 14)

Vic

· Operating temperature Topr

20 to +75

°C

· Storage temperature

Tstg

65 to +150

°C

· Allowable power dissipation

(A2020M) 1000

(A2020S) 900

· LED drive current

LED

Operating Supply Voltage Range

8.5 to 9.5

CXA2020M/S

E94Y28-ST

EIAJ Sound Multiplexing Decoder

Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by
any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the
operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.

CXA2020S

22 pin SDIP (Plastic)

CXA2020M

28 pin SOP (Plastic)

GND

REFL

Vcc

MO MODE

MPX IN

CUBI

LEDST

LEDSU

LEDM

SUBI

SC OUT

SC IN

MC OUT

MC IN

L OUT

R OUT

M OUT

FOMO

MUTE

MODE

CXA2020S

GND

REFL

Vcc

MO MODE

MPX IN

CUBI

LEDST

LEDSU

LEDM

SUBI

SC OUT

SC IN

MC OUT

MC IN

L OUT

R OUT

M OUT

FOMO

MUTE

MODE

CXA2020M

CXA2020M

CXA2020S

CXA2020M/S

Block Diagram

CXA2020M

CXA2020S

I
N

IBIAS

VOLTAGE
REGULATOR

BIAS
CURRENT

BUFFER

BIAS
VOLTAGE

MPX SIGNAL

I
N

4.5f

TRAP

SUB

BPF

SUB
DET

CUE

BPF

AM
DEMOD

952Hz
BPF

COMP

LED
DRIVE

3.5f

VCO

CUE
CARRIER

952Hz
CLOCK

3.5f

CLOCK

IIL LOGIC & CONT

MAIN

OUT

OUTPUT AMP

& OUTPUT SW

MATRIX

SUB

MAIN

L R

MAINDEEM

SUBDEEM

FM
DEMOD

I
N

IBIAS

VOLTAGE
REGULATOR

BIAS
CURRENT

BUFFER

BIAS
VOLTAGE

MPX SIGNAL

I
N

4.5f

TRAP

SUB

BPF

SUB
DET

CUE

BPF

AM
DEMOD

952Hz
BPF

COMP

LED
DRIVE

3.5f

VCO

CUE
CARRIER

952Hz
CLOCK

3.5f

CLOCK

IIL LOGIC & CONT

MAIN

OUT

OUTPUT AMP

& OUTPUT SW

MATRIX

SUB

MAIN

L R

TEST

MAINDEEM

SUBDEEM

FM
DEMOD

CXA2020M/S

Pin Description (Ta = 25°C, V

= 9V)

The pin numbers in parentheses are for the CXA2020S.

PIn No.

SDIP

SOP

Symbol

GND

GND.

2
7

2
5
8

10
14
15
24
27

Keep these pins open.
(They are not
connected to the chip.)

REFL

1.2V

The noise elimination
filter connection of
internal reference
voltage.

MPXIN

4.1V

Sound multiplexing
signal input.
Typical input level

= 70mVrms

(monaural, 100%)

CUBI

4.1V

Bias capacitor
connection of Cue
pulse generator.

MO MODE

Forced monaural mode
selection.
When Low or open, the
forced monaural mode
operates for stereo
broadcasts only;
if High, the forced
monaural mode
operates for both
stereo and bilingual
broadcasts.

Power supply.

voltage

Equivalent circuit

Description

Vcc

147

GND

3.3k

20k

24k

GND

(5)

10.5k

50k

70k

Vcc

147

80µ

GND

138k

(6)

25k

30k

4.2V

Vcc

147

(8)

40k

Vcc

11k

4.2V

CXA2020M/S

Pin No.

SDIP

SOP

Symbol

LEDST

LEDM

MODE

LEDSU

Mode indicator LED
connection.

Pin 11 (9): stereo
Pin 12 (10): sub
Pin 13 (11): main

DC voltage-based
output mode switch for
bilingual broadcasts.

MUTE

Output muting.
When High, only DC is
output from Pins 19, 20
and 21 (15, 16 and 17).

FOMO

Forced monaural.
When High, forced
monaural (main sound)
mode is selected and
the LED turns off.

MOUT

4.1V

Main signal output.
Always outputs the main
signal component,
regardless of the
broadcast mode.

voltage

Equivalent circuit

Description

GND

(9)

(10)

(11)

64k

16k

10.5k

64k

16k

10.5k

64k

16k

10.5k

(12)

20k

10.5k

40k

16k

Vcc

20µ

GND

4.2V

GND

(13)

10.5k

50k

70k

GND

(14)

10.5k

50k

70k

(15)

Vcc

147

GND

17.2k

1.5m

32k

Vcc

CXA2020M/S

Pin No.

SDIP

SOP

Symbol

ROUT

4.1V

R-ch output.

LOUT

4.1V

L-ch output.
During "TEST", the Cue
signal component
passed through the Cue
BPF is output.

MCIN

4.1V

MCOUT

3.4V

DC cut capacitor
connection of main
signal.

SCIN

4.1V

SCOUT

3.9V

DC cut capacitor
connection of sub
signal.

SUBI

4.1V

Bias capacitor
connection of sub FM
detector. "TEST" mode,
used for filter
adjustment, is
activated by grounding
this pin.

voltage

Equivalent circuit

Description

(22)

147

64k

Vcc

20µ

80µ

16k

1.7V

4.2V

147

16k

Vcc

4.2V

147

80µ

20P

Vcc

80µ

GND

(21)

Vcc

147

(20)

Vcc

16k

4.2V

320µ

40k

(19)

(18)

Vcc Vcc

147

16k

4.2V

147

160µ

147

80µ

20P

GND

Vcc

(17)

Vcc

147

GND

17.2k

1.5m

32k

Vcc

(16)

Vcc

147

GND

17.2k

1.5m

32k

Vcc

CXA2020M/S

Electrical Characteristics Measurement Circuit (CXA2020M)

CXA2020M

GND

SIGNAL

SIG

ATT

SW5

E1
9V

47µF

10µF

GND

10µF

910

I
N

GND

SW1

SW2

SW3

15kHz
LPF

CCIR
FILTER

MEASUREMENT
SYSTEM

RMS
DISTORTION
DCVOLT

I
N

C10

1µF

C10

10µF

OFF

SW6

TEST

(ON)

NORM

(OFF)

SW4

ATT is set to bring L

R stereo separation to a minimum.

CXA2020M/S

Electrical Characteristics (Ta = 25°C, V

= 9V) The pin numbers in parentheses are for the CXA2020S.

No.

Item

Symbol

condi-

tions

Bias

condi-

tions

Conditions

Measure-

ment

point

Min.

Typ.

Max.

Unit

Current
consumption

Sub output
level 400Hz

Sub frequency
characteristics
1kHz

Sub frequency
characteristics
10kHz

Sub distortion

Sub S/N ratio

Stereo
distortion
L-ch

Stereo
distortion
R-ch

Vs1

Fs1

Fs2

Dstl

Dstr

and

Measure current
input to Pin 4

Input signal: SIG1
Measure output amplitude
(400Hz, sine wave)
of Pins 20 and 21
(16 and 17): Vs1

(15kLPF)

Input signal: SIG2
Measure output amplitude
(1kHz, sine wave)
of Pins 20 and 21
(16 and 17): Vs2

Fs1 = 20log

(15kLPF)

Input signal: SIG3
Measure output amplitude
(10kHz, sine wave)
of Pins 20 and 21
(16 and 17): Vs3

Fs2 = 20log

(15kLPF)

Input signal: SIG2
Measure distortion
of output signal
(1kHz, sine wave)
of Pins 20 and 21
(16 and 17)

(15kLPF)

Input signal: SIG2
Measure S/N ratio
of output (1kHz)
of Pins 20 and 21
(16 and 17)

(15kLPF, RMS)

Input signal: SIG4
Measure distortion
of output signal
(1kHz, sine wave)
of Pin 21 (17)

(15kLPF)

Input signal: SIG5
Measure distortion
of output signal
(1kHz, sine wave)
of Pin 20 (16)

(15kLPF)

Pin 4

Pins 20
and 21
(16 and
17)

Pin 21
(17)

Pin 20
(16)

480

1.6

19.0

580

0.6

16.5

0.2

690

14.0

1.5

mVrms

Vs2
Vs1

Vs3
Vs1

When bias condition is "3", measurement point is Pin 20 only.

CXA2020M/S

Stereo
output level
L-ch 1kHz

Stereo
output level
R-ch 1kHz

Main
output level
MAIN OUT

Main
output level

Main
frequency
characteristics
1kHz

Main
frequency
characteristics
10kHz

Main distortion
MAIN OUT

Vstl

Vstr

Vm1

Vm2

Fm1

Fm2

Dm1

Input signal: SIG4
Measure output
amplitude
(1kHz, sine wave)
of Pin 21 (17)

(15kLPF)

Input signal: SIG5
Measure output
amplitude
(1kHz, sine wave)
of Pin 20 (16)

(15kLPF)

Input signal: SIG6
Measure output signal
(400Hz, sine wave) of
Pin 19 (15)

(15kLPF)

Input signal: SIG6
Measure amplitude of
output signal
(400Hz, sine wave) of
Pins 20 and 21 (16 and 17)

(15kLPF)

Input signal: SIG7
Measure output amplitude
(1kHz, sine wave) of
Pins 20 and 21

(16 and 17): Vm3

Fm1 = 20log

(15kLPF)

Input signal: SIG8
Measure output amplitude
(10kHz, sine wave) of
Pins 20 and 21

(16 and 17): Vm4

Fm2 = 20log

(15kLPF)

Input signal: SIG7
Measure distortion of
output signal
(1kHz, sine wave) of
Pin 19 (15)

(15kLPF)

Pin 21
(17)

Pin 20
(16)

Pin 19
(15)

Pins
20 and 21
(16 and
17)

Pin 19
(15)

440

480

1.6

16.0

540

580

0.6

14.0

0.2

640

690

12.0

mVrms

Vm3
Vm2

Vm4
Vm2

No.

Item

Symbol

condi-

tions

Bias

condi-

tions

Conditions

Measure-

ment

point

Min.

Typ.

Max.

Unit

CXA2020M/S

Main distortion

Main distortion
at maximum
input

Main S/N ratio

Stereo
separation
L

Stereo
separation
R

Cross talk
MAIN

SUB

Dm2

Dm3

Sstr

Sstl

Cms1

Input signal: SIG7
Measure distortion of
output signal
(1kHz, sine wave) of
Pins 20 and 21
(16 and 17)

(15kLPF)

Input signal: SIG9
Measure distortion of
output signal
(1kHz, sine wave) of
Pins 20 and 21
(16 and 17)

(15kLPF)

Input signal: SIG7
Measure S/N ratio of
output signal (1kHz) of
Pins 20 and 21
(16 and 17)

(15kLPF. RMS)

Input signal: SIG4
Sstr =

20log

(dB)

(15kLPF)

Input signal: SIG5
Sstl =

20log

(dB)

(15kLPF)

Input signal: SIG15
Calculate the level
difference between the
output amplitude of Pins
20 and 21 (16 and 17)
(Vms1) and the
measured value (Vm3)
in measurement No. 13

Cms1 = 20log

(dB)

(15kLPF, 1kBPF)

Pins
20 and 21
(16 and
17)

0.2

0.3

Output amplitude

Pin 21 (17)

Output amplitude

Pin 20 (16)

Output amplitude

Pin 20 (16)

Output amplitude

Pin 21 (17)

Vm3

Vms1

No.

Item

Symbol

condi-

tions

Bias

condi-

tions

Conditions

Measure-

ment

point

Min.

Typ.

Max.

Unit

CXA2020M/S

Cross talk
SUB

MAIN

Cross talk
MAIN

SUB

BOTH mode

Cross talk
SUB

MAIN

BOTH mode

Residual
carrier
SUB

Residual
carrier
MAIN

Mute volume
MAIN

Csm1

Cms2

Csm2

Lcs

Lcm

Input signal: SIG2
Calculate the level
difference between the
output amplitude of Pins
20 and 21 (16 and 17)
(Vsm1) and the
measured value (Vs2)
in measurement No. 3.

Csm1 = 20log

(dB)

(15kLPF, 1kBPF)

Input signal: SIG15
Calculate the level
difference between the
output amplitude of
Pin 20 (16) (Vms2) and
the output amplitude of
Pin 21 (17) (Vms3).

Cms2 = 20log

(dB)

(15kLPF, 1kBPF)

Input signal: SIG2
Calculate the level
difference between the
output amplitude of
Pin 21 (17) (Vsm2) and
the output amplitude of
Pin 20 (16) (Vsm3).

Csm2 = 20log

(dB)

(15kLPF, 1kBPF)

Input signal: SIG11
Measure subcarrier
component amplitude
of the output of Pins 20
and 21 (16 and 17).

Input signal: SIG11
Measure the subcarrier
component amplitude
of the output of Pins 20
and 21 (16 and 17).

Input signal: SIG7
Calculate the level
difference between the
output amplitude of Pins
20 and 21 (16 and 17)
(VMm) and the
measured value (Vm3)
in measurement No. 13.

Mm = 20log

(dB)

(15kLPF, 1kBPF)

Pins
20 and 21
(16 and
17)

mVrms

Vs2

Vsm1

Vms3
Vms2

Vsm3
Vsm2

Vm3

VMm

No.

Item

Symbol

condi-

tions

Bias

condi-

tions

Conditions

Measure-

ment

point

Min.

Typ.

Max.

Unit

CXA2020M/S

Mute volume
SUB

Mute volume
stereo

DC offset
stereo L-ch

DC offset
stereo R-ch

DC offset
MAIN OUT

Cue detection
sensitivity

SUB detection
sensitivity

Mst

Ostl

Ostr

and

Input signal: SIG2
Caluculate the level
difference between the
output amplitude of Pins
20 and 21 (16 and 17)
(VMs) and the
measured value (Vs2)
in measurement No. 3.

Ms = 20log

(dB)

(15kLPF, 1kBPF)

Input signals: SIG4, 5
Measure the level
difference between the
output signals of Pins 20
and 21 (16 and 17)
under bias conditions
2 and 4.
Mst =

20log

Input signal: SIG18
Measure the fluctuation
in the output DC level of
Pin 21 (17) under bias
conditions 2 and 4.

Input signal: SIG18
Measure the fluctuation
in the output DC level of
Pin 20 (16) under bias
conditions 2 and 4.

Input signal: No signal
Measure the fluctuation
in the output DC level of
Pin 19 (15) under bias
conditions 2 and 4.

Input signal: SIG12
Change SIG12 and
measure amount of
attenuation at the point
"monaural" switches to
"Sound multiplex".

Input signal: SIG13
Change SIG13 and
measure amount of
attenuation at the point
"monaural" switches to
"Sound multiplex".

Pins
20 and 21
(16 and
17)

Pin 21
(17)

Pin 20
(16)

Pin 19
(15)

100

Vs2

VMs

Measured value

under bias

condition 2 (mVrms)

Measured value

under bias

condition 4 (mVrms)

Measure Pin 21 for SIG4 input; Pin 20 for SIG5 input.

No.

Item

Symbol

condi-

tions

Bias

condi-

tions

Conditions

Measure-

ment

point

Min.

Typ.

Max.

Unit

CXA2020M/S

Cue BPF gain

4.5f

trap

attenuation
level

Input signal: SIG14
Measure the output
amplitude of Pin 21 (17).

Input signal: SIG16, 17
Measure output
amplitude of Pin 28 (22)
and then measure the
level difference in the
output signal for SIG16
input and SIG17 input.
TG =

20log

Pin 21
(17)

Pin 28
(22)

330

480

620

mVrms

Measured value

for SIG16

(mVrms)

Measured value

for SIG17

(mVrms)

SW Condition Table

off

BIAS Condition Table

BIAS

0.5V

4.5V

2.5V

4.5V

0.5V

4.5V

off

No.

Item

Symbol

condi-

tions

Bias

condi-

tions

Conditions

Measure-

ment

point

Min.

Typ.

Max.

Unit

CXA2020M/S

Input Signal Definition

SIG1 : Sound MPX signal

Main

: 0%

Sub

: 400Hz, 100% MOD

Cue

: Bilingual

SIG2 : Sound MPX signal

Main

: 0%

Sub

: 1kHz, 100% MOD

Cue

: Bilingual

SIG3 : Sound MPX signal

Main

: 0%

Sub

: 10kHz, 100% MOD

Cue

: Bilingual

SIG4 : Sound MPX signal

L-ch

: 1kHz, 100%

R-ch

: 0%

Cue

: Stereo

SIG5 : Sound MPX signal

L-ch

: 0%

R-ch

: 1kHz, 100%

Cue

: Stereo

SIG6 : Sound MPX signal

Main

: 400Hz, 100%

Sub

: Carrier off

Cue

: Cue signal off

SIG7 : Sound MPX signal

Main

: 1kHz, 100%

Sub

: Carrier off

Cue

: Cue signal off

SIG8 : Sound MPX signal

Main

: 10kHz, 100%

Sub

: Carrier off

Cue

: Cue signal off

SIG9 : Sound MPX signal

Main

: 1kHz, 300%

Sub

: Carrier off

Cue

: Cue signal off

SIG10 : Sound MPX signal

L-ch

: 1kHz, 100%

R-ch

: 0%

Cue

: Cue signal off

SIG11 : Sound MPX signal

Main

: 0%

Sub

: 0% (Carrier only)

Cue

: Bilingual

SIG12 : Sound MPX signal

Main

: 0%

Sub

: 0% (Carrier only)

Cue

: Bilingual (level adjusted to minimum)

SIG13 : Sound MPX signal

Main

: 0%

Sub

: 0% (level adjusted to minimum)

Cue

: Bilingual

SIG14 : 55.069kHz sine wave

5.6mVrms

SIG15 : Sound MPX signal

Main

: 1kHz, 100%

Sub

: 0% (Carrier only)

Cue

: Bilingual

SIG16 : 31.47kHz sine wave

42mVrms

SIG17 : 70.80kHz sine wave

42mVrms

SIG18 : Sound MPX signal

L-ch

: 0%

R-ch

: 0%

Cue

: Stereo

Sound MPX signal level is defined as 100% MONO

at 1Vp-p.

CXA2020M/S

Output and LED On/Off Table

MODE SW

SUB BOTH MAIN

Forced

monaural

MODE

Forced

monaural

MUTE

MAIN STEREO

SUB

MAIN

Output condition

LED On/Off condition

Broadcast

condition

Stereo

×
×
×

×
×
×
×

×
×
×

×
×
×
×

×
×
×

×
×
×
×

×
×
×

F.MONO

F.MAIN

×
×
×

OFF

×
×
×
×

OFF

×
×
×

OFF

L + R

SUB

MAIN

SUB

MAIN

MONO

L + R

SUB

MAIN

SUB

MAIN

MONO

L + R

MAIN

MONO

OFF

Bilingual

Monaural

: No response

Control Voltage Range

The information in parentheses is for the CXA2020S.

MODE SW

Pin 16 (Pin12)

SUB

BOTH

MAIN

off

F.MAIN

F.MONO

Voltage range

4.5V to V

2V to 3V(or open)

0V to 0.5V

3V to V

0V to 0.5V (or open)

3V to V

0V to 0.5V (or open)

3V to V

0V to 0.5V (or open)

Forced monaural

Pin 18 (Pin 14)

MUTE

Pin 17 (Pin 13)

Forced monaural mode

Pin 6 (Pin 5)

Description of Operation

The information in parentheses is for the CXA2020S.

The sound mutiplexing signal input from Pin 7 (Pin 6) is passed through IN AMP and is applied to the Cue
BPF, Sub BPF, and Main de-emphasis circuit.
1. Discrimination circuits

Cue BPF passes only the Cue signal component from the multiplex signal. In the AM demodulator, the
signal (AM wave) is AM detected and one of two sine waves is generated, either a 922.5Hz signal for
bilingual broadcasts or a 982.5Hz signal for stereo broadcasts.
In the 952Hz BPF, the 3.5f

carrier component is eliminated from the Cue signal after AM wave detection.

The Cue signal, from which the carrier component has been eliminated, is waveform shaped by COMP,
with the resulting 922.5Hz or 982.5Hz pulse being applied to the Logic section.
In the 3.5f

VCO, a 3.5f

pulse locked onto the Cue signal carrier (3.5f

) is created and sent to the Logic

section.
In the Logic section, the broadcast mode is identified using the countdown method. Depending on this
result as well as the presence of a SUB signal from SUB detector and the MUTE ON/OFF, MODE
switching, and FOMO ON/OFF instructions from CONT, the output switching control signal is created. This
signal is used to control the output condition of OUTPUT SW and MAIN OUT.

CXA2020M/S

2. Main circuits

In MAIN DEEM, de-emphasis is applied to the Main signal component and the Sub and Cue components
are removed.
After passing through the MAIN DEEM, the Main signal is applied to MATRIX, OUTPUT AMP, and
MAINOUT.

3. Sub circuits

In SUB BPF, only the SUB signal component out of multiplex signals is passed through. In the 4.5f

trap,

the digital facsimile signal component is removed.
In FM Demod, the SUB signal is FM demodulated.
In SUB DEEM, the FM demodulated Sub signal is de-emphasized and the carrier component is removed.
After passing through SUB DEEM, the Sub signal is applied to MATRIX and OUTPUT AMP.

4. MATRIX and output circuits

In MATRIX, the L and R signals are created by adding and subtracting the Main signal from MAIN DEEM
and the Sub signal from SUB DEEM in stereo broadcast.
In OUTPUT AMP and OUTPUT SW, the output signal is switched under the control of Logic.
In addition, MAIN OUT always outputs the MAIN signal component, regardless of the broadcast mode.

Adjustment

Separation adjustment

Fig. 1

Procedure

1) Connect components as shown in Fig. 1. (Set SW4 to NORM.)

2) Set the encoder to stereo mode, and input a 100% modulated 1kHz signal; also set the encoder so that

only the L-ch is output.

3) Monitor the oscilloscope and AC voltmeter and adjust VR2 so that the R-ch is at a minimum.

(Separation standard: 35dB or more)

EIAJ sound multiplexing encoder

MPX IN

VR2

Oscilloscope

Application circuit

L. OUT

R. OUT

CH1 CH2

Switch

1kHz BPF

AC Voltmeter

CXA2020M/S

CXA2020S

Application Circuit

CXA2020M

GND

47µF

10µF

910

I
N

R7
3.6k

I
N

1µF

C10

10µF

TEST

(ON)

NORM

(OFF)

SW4

VR2

I
N

70mVrms
(MONO
100%)

SW5

.

M

I
N

.

M

Vcc

I
N

SW1

BOTH

2.4k

SW2

SW3

10µF

SW5: F. MONO- Forced monaural mode operates only for stereo.

F. MAIN- Forced monaural mode operates for both stereo and bilingual.

CXA2020S

GND

47µF

10µF

910

I
N

R7
3.6k

I
N

1µF

C10

10µF

TEST

(ON)

NORM

(OFF)

SW4

VR2

I
N

70mVrms
(MONO
100%)

SW5

.

M

I
N

.

M

Vcc

SUB

MAIN

SW1

BOTH

2.4k

SW2

SW3

10µF

SW5: F. MONO- Forced monaural mode operates only for stereo.

F. MAIN- Forced monaural mode operates for both stereo and bilingual.

Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for
any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same.

CXA2020M/S

Example of Representative Characteristics

De-emphasis characteristics

t
p

t

l
e

l

[
d

]

Frequency [Hz]

Main

100

10k

SUB BPF frequency characteristics

t
p

t

l
e

l

[
d

]

Frequency [kHz]

40 50

60 70 80

100

Cue BPF frequency characteristics

t
t
e

t
i
o

l
e

l

[
d

]

Frequency [Hz]

3.5f

40k

3.5f

20k

3.5f

+20k

3.5f

+40k

MAIN distortion characteristics

i
s

t
o

r
t
i
o

[
%

]

MAIN modulation factor [%]

100

200

300

400

500

Sub

CXA2020M/S

Package Outline

Unit: mm

CXA2020M

CXA2020S

SONY CODE

EIAJ CODE

JEDEC CODE

SOP-28P-L04

PACKAGE STRUCTURE

PACKAGE MATERIAL

LEAD TREATMENT

LEAD MATERIAL

PACKAGE WEIGHT

42 ALLOY

SOLDER PLATING

EPOXY / PHENOL RESIN

28PIN SOP (PLASTIC) 375mil

18.8 0.1

+ 0.4

0.45 ± 0.1

1.27

.
3

2.3 0.15

+ 0.4

0.1 0.05

+ 0.2

.
5

.
2

0.2 0.05

+ 0.1

.
6

.
1

.
3

.
4

0.15

± 0.12

SOP028-P-0375-D

0.7g

SONY CODE

EIAJ CODE

JEDEC CODE

PACKAGE STRUCTURE

MOLDING COMPOUND

LEAD TREATMENT

LEAD MATERIAL

PACKAGE WEIGHT

EPOXY RESIN

SOLDER PLATING

COPPER ALLOY

22PIN SDIP (PLASTIC)

SDIP-22P-01

SDIP022-P-0300

0.95g

1.778

19.2 0.1

+ 0.4

.
6

.
4

.
1

.
3

.
2

.
0

.
1

0° to 15°

0.5 ± 0.1

0.9 0.1

+ 0.15

.
2

.
1

.
5

I
N

.
9

.
1

.
4

Ð­Ð»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: CXA2020S

ÐÐ»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: CXA2020S