TOSHIBA TC90L01NG

TC90L01NG
TOSHIBA Linear C-MOS Integrated Circuit
Silicon Monolithic
TC90L01NG(TENTATIVE)
Audio/Video Switching IC for TVs
TC90L01NG
The TC90L01NG is an audio/video switching IC for
TV sets.
2
Conforming to I C bus standards, it allows you to
perform various switching operations through the
bus lines by using a microcomputer. This IC has the
Weight
SDIP24-P-300-1.78 : 1.22 g (typ.)
functions of audio mute, ALC(Auto Level Control),
audio volume and so on.
Features
2
I C bus control
Video : 3-channel inputs and 1-channel outputs
(1 channels conforming to S system)
Audio : 3-channel inputs and 1-channel outputs
Monitor Audio out
ALC(Auto Level Control)
Audio volume by attenator circuit
Audio mute
2 I/O ports
1
2006/02/16
TC90L01NG
Block Diagram
V1-V/Y in
V2-V in
TV-V in
VCC
12
VCC
GND
15
GND
22
V out
18
Y out
20
C out
14
SCL
13
SDA
19
I/O-1
21
I/O-2
17
TV-L out
4
8
2
+
S
V1-C in
6
Mute
24
2
I C
BUS
ALC
10
ALC
2
I L
Logic
V1-L in
V2-L in
TV-V in
5
9
1
Volume
I/O
24
Mon-L out
Volume
V1-R in
V2-R in
TV-R in
7
11
3
2
16
TV-R out
23
Mon-R out
2006/02/16
TC90L01NG
Pin Assignment
TC90L01NG
1 TV-L in
Mon-L out 24
2 TV-V in
Mon-R out 23
3 TV-R in
V out 22
4 V1-V/Y in
I/O-2 21
5 V1-L in
C out 20
11
6 V1-C in
TC90L01NG
I/O-1 19
7 V1-R in
Y out 18
8 V2-V in
TV-L out 17
9 V2-L in
TV-R out 16
10 ALC
GND 15
11 V2-R in
SCL 14
12 VCC
SDA 13
3
2006/02/16
TC90L01NG
Pin Description
Pin
No.
1
Name
TV-L in
Function
Interface
This pin is for input a left audio
signal from the main demodulator in
the TV set. The signal fed into this
pin is presented to TV-L out, and
Mon-L out.
The input dynamic range of this pin
is 5.0 Vp-p and the input resistance is
120 kΩ.
300
Audio Out
Audio In
120k
4.5V
2
TV-V in
This pin is for input a composite
audio signal from the main
demodulator in the TV set. The
signal fed into this pin is presented
to V out, Y out, and C out.
The input dynamic range of this pin
is 2.0 Vp-p and the input resistance is
30 kΩ.
3
TV-R in
60k
Y out
C out
200
Vi deo
In
60k
This pin is for input a right audio
signal from the main demodulator in
the TV set. The signal fed into this
pin is presented to TV-R out, and
Mon-R out.
The input dynamic range of this pin
is 5.0 Vp-p and the input resistance is
120 kΩ.
V out
300
Audio Out
Audio In
120k
4.5V
4
V1-V/Y in
This pin is for input a luminance
signal or composite video signal
from an external source (V1
channel). The signal fed into this pin
is presented to V out, Y out, and C
out.
The input dynamic range of this pin
is 2.0 Vp-p and the input resistance is
30 kΩ.
4
60k
Y out
C out
200
Vi deo
In
60k
2006/02/16
V out
TC90L01NG
Pin
No.
5
Name
V1-L in
Function
Interface
This pin is for input a left audio
signal from an external source (V1
channel). The signal fed into this pin
is presented to TV-L out, and Mon-L
out.
The input dynamic range of this pin
is 5.0 Vp-p and the input resistance is
120kΩ.
300
Audio Out
Audio In
120k
4.5V
6
7
V1-C in
V1-R in
This pin is for input a chroma signal
from an external source (S1
channel). The signal fed into this pin
is presented to C out directly and to
V out after being combined with the
V1-Y in signal.
The input dynamic range of this pin
is 2.0 Vp-p and the input resistance is
30 kΩ.
This pin is for input a right audio
signal from an external source (V1
channel). The signal fed into this pin
is presented to TV-R out, and
Mon-R out.
The input dynamic range of this pin
is 5.0 Vp-p and the input resistance is
120 kΩ.
60k
Y out
C out
200
V out
Vi deo
In
60k
300
Audio Out
Audio In
120k
4.5V
8
V2-V in
This pin is for input a composite
video signal from an external source
(V2 channel). The signal fed into this
pin is presented to V out, Y out, and
C out.
The input dynamic range of this pin
is 2.0 Vp-p and the input resistance is
30 kΩ.
5
60k
Y out
C out
200
Vi deo
In
60k
2006/02/16
V out
TC90L01NG
Pin
No.
9
Name
V2-L in
Function
Interface
This pin is for input a left audio
signal from an external source (V2
channel). The signal fed into this pin
is presented to TV-L out and Mon-L
out.
The input dynamic range of this pin
is 5.0 Vp-p and the input resistance is
120Ω.
300
Audio Out
Audio In
120k
4.5V
10
ALC
This is an detect output pin of
ALC[:Auto Level Control]. It controls
ALC.
100
ALC
ALC
11
V2-R in
This pin is for input a right audio
signal from an external source (V2
channel). The signal fed into this pin
is presented to TV-R out and Mon-R
out.
The input dynamic range of this pin
is 5.0 Vp-p and the input resistance is
120 kΩ.
300
Audio Out
Audio In
120k
4.5V
12
VCC
This is the power supply pin. Apply 9
V to this pin. The current
consumption of this pin is 34 mA.

5.0V
13
SDA
This is an I2C bus data input/output
pin. The input threshold level of this
pin is 3.0 V.
Make sure that the current flowing
into this pin is 3.0 mA or less.
6
LO G IC
13
SDA
3.0V
2006/02/16
TC90L01NG
Pin
No.
Name
Function
Interface
5.0V
LOGIC
14
SCL
This is an I2C bus data input/output
pin. The input threshold level of this
pin is 3.0 V.
14
SCL
3.0V
15
16
17
18
GND
This is the GND pin.
TV-R out
This pin is for output right audio
signal. The signal fed into TV-R in,
V1-R in, or V2-R in is outputted from
this pin.
This outputted can be muted
independently of TV-L out by bus
control.
TV-L out
Y out

This pin is for output left audio
signal. The signal fed into TV-L in,
V1-L in, or V2-L in is outputted from
this pin.
This output can be muted
independently of TV-R out by bus
control.
This pin is for output a luminance
signal. The signal fed into V1-V/Y in,
V2-V in, or TV-V in is outputted from
this pin.
7
Audio Out
Audio Out
Video Out
2006/02/16
TC90L01NG
Pin
No.
Name
Function
Interface
This is an ADC input/DAC output
pin.
19
I/O－１
The ADC is a 2-level detection type
(1 bits). The threshold level is 3.0 V.
I/O
The DAC (1 bit) is an open-drain
output. Make sure that the current
flowing into this pin is 2.0 mA or
less.
20
C out
3.0V
This pin is for output a chroma
signal. The signal fed into V1-C in,
V1-V in, V2-V in , or TV-V in is
outputted from this pin.
Video Out
This is an ADC input/DAC output
pin.
21
I/O－２
The ADC is a 2-level detection type
(1 bits). The threshold level is 3.0 V.
I/O
The DAC (1 bit) is an open-drain
output. Make sure that the current
flowing into this pin is 2.0 mA or
less.
22
V out
3.0V
This pin is for output the main
channel composite video signal. The
signal fed into TV-V in, V1-V in,
V2-V in, or V1-Y in +AV1-C in is
outputted from this pin.
Video Out
This output can be muted by bus
control.
8
2006/02/16
TC90L01NG
Pin
No.
23
Name
Mon-R out
Function
Interface
This pin is for monitor-output right
audio signal. The signals fed into the
chip via V1-R in, V2-R in, or TV-R in
is output from this pin.
This output can be muted in
combination with Mon-L out by bus
control.
24
Mon-L out
Audio Out
This pin is for monitor-output left
audio signal. The signals fed into the
chip via V1-L in, V2-L in, or TV-L in
is output from this pin.
This output can be muted in
combination with Mon-R out by bus
control.
9
Audio Out
2006/02/16
TC90L01NG
Bus Data Specifications
Contents of Data
Sub
Data No.
Add.
[Preset]
Mode
Contents of Data
B07
00
[00H]
Write
Data 2
01
02
[00H]
B04
B03
B02
B01
B00
Output switching
＊
B17
ALC Gain
B16
B15
Select-D
Select-C
Select-B
B14
B13
B12
B11
B10
B22
B21
B20
Audio
Mute
Select-A
Audio attenator
B27
B26
B25
B24
＊
＊
＊
＊
B37
－
B05
B23
Data 3
[03H]
Read
B06
Data 1
Data 4
Power on
Reset
B36
B35
＊
DAC output switching
B34
＊
＊
I/O-2
I/O-1
B33
B32
B31
B30
S input
discriminati
on
ADC input discrimination
＊
＊
＊
I/O-2
I/O-1
Note1: The data contents marked by a ＊ are an unused bit (data free).
10
2006/02/16
V1-C in
TC90L01NG
Slave Add.＝
＝90H
WRITE mode
Item
Bits
Descriptions
Select－Ａ
Sub; 00 h,D0～D1
（Note 2）
Select－Ｂ
Sub; 00 h,D2
Select－Ｃ
Sub; 00 h,D3
Select－Ｄ
Sub; 00 h,D4
ＡＬＣ Level
Sub; 00 h,D5～D6
２
Select input function
00: ＴＶ
01: External 1
10: External 2
11: －（Inhibited）
ＣＶＢＳ or Ｓ-video switching
0: ＣＶＢＳ
1: Ｓ-video
Monitor-Video out
0: Normal
1: Mute
Monitor-Audio out
0: Normal
1: Mute
Audio Level Control Gain
00: ＡＬＣ off
01: 1.1Vp-p
10: 1.6Vp-p
11: 2.3Vp-p
Audio Volume
00: -∞
～
7F: 0dB
Audio Mute
0: Normal
1: Mute
DAC output switching
0: Low
1: High
Audio Vol.
Sub; 01h,D0～D6
Audio mute on/off
Sub; 01h,D7
I/O-* High/Low
Sub; 02h,D1,D2
１
１
１
２
７
１
１×２
Preset
00
0
0
0
10
00
0
1
Note 2：Select-Ａ＝｛１１｝not use.
READ mode
Slave Add.＝
＝91H
Item
Bits
Description
POR
１
V1-C in
１
I/O *
１×２
Power on Reset
0: Normal
1: Resister Preset
S input discrimination
0: GND
1: Open
ADC input discrimination
0: Low
1: High
11
2006/02/16
TC90L01NG
Video Select: Terminal 22 , 18 , 20 Output Signal
Audio Select: Terminal 17 , 16 , 24 , 23 Output Signal
Mode
Video Output Signal
Bus Data
Audio Output Signal
Input Select
Input
TV
S/V
V out
Y out
TV-L out
TV-R out
B02
Mon-L out
Mon-R out
B
C out
B01
B00
A
CVBS
TV-V in
TV-V in
TV-V in
TV-L in
TV-R in
0
0
0
CVBS
V1-V in
V1-V in
V1-V in
V1-L in
V1-R in
0
0
1
S
V1-Y in
+ V1-C
in
V1-Y in
V1-C in
V1-L in
V1-R in
1
0
1
V2
CVBS
V2-V in
V2-V in
V2-V in
V2-L in
V2-R in
0
1
0
V3
-
－
－
－
－
－
0
1
1
V1
DAC Output Switching
Bus Data
Mode
DAC Output Switching
Output
I/O-1
State
Low
B23
B22
B21
＊
＊
＊
Open
I/O-2
Low
B20
0
1
＊
0
＊
Open
＊
1
12
2006/02/16
TC90L01NG
Read Mode
Power-On Reset Discrimination
Bus Data
Mode
Power-On Reset
B37
Reset
On (Preset)
1
off (Normal)
0
S Input Discrimination
Bus Data
Mode
S Input Discrimination
Input
V1-C in
Voltage
B30
High (open)
1
Low
0
ADC Input Discrimination
Bus Data
Mode
ADC Input Discrimination
Input
Voltage
B34
B33
B32
＊
＊
＊
High
I/O-1
1
Low
0
High
1
＊
I/O-2
B31
＊
Low
＊
0
13
2006/02/16
TC90L01NG
2
Outline of I C Bus Control Format
DATA TRANSFER FORMAT VIA I2C BUS
Start and stop condition
SDA
SCL
S
P
Start condition
Stop condition
Bit transfer
SDA
SCL
SDA stable
Change of SDA allowed
Acknowledge
SDA by
transmitter
The transmitter releases the SDA line (HIGH)
during the acknowledge clock pulse.
SDA by
receiver
SCL from
master
The receiver has to pull down the SDA line
(LOW) during the acknowledge clock pulse.
S
1
8
9
Clock pulse for acknowledgment
14
2006/02/16
TC90L01NG
Data transmit format 1
S
Slave address
0 A
Sub address
7bit
A
Transmit data
8bit
MSB
S : Start condition
A P
8bit
MSB
A : Acknowledge
MSB
P : Stop condition
Data transmit format 2
S
Slave address
0 A
Sub address
A
Transmit data 1
Sub address
A
A
Transmit data n
A P
Data received format
S
Slave address
1 A
Received data 01
7bit
A
Received data 02
A P
8bit
MSB
MSB
At the moment of the first acknowledge, the master transmitter becomes a master receiver and the
slave receiver becomes a slave transmitter. This acknowledge is still generated by the slave.
The Stop condition is generated by the master.
Optional data transmit format : automatic increment mode
S
Slave address
0 A 1
7bit
Sub address
A
Transmit data 1
Transmit data n
8bit
8bit
7bit
MSB
MSB
MSB
MSB
In this transmission methods, data is set on automatically incremented sub-address from the
specified sub-address.
I2C BUS Conditions
Characteristics
Symbol
Min
Typ.
Max
Unit
Low level input voltage
High level input voltage
Low level output voltage at 3 mA sink current
Input current each I/O pin with an input voltage
between 0.1 VDD and 0.9 VDD
Capacitance for each I/O pin
SCL clock frequency
Hold time START condition
Low period of SCL clock
High period of SCL clock
Set-up time for a repeated START condition
Data hold time
Data set-up time
Set-up time for STOP condition
Bus free time between a STOP and START
condition
VIL
VIH
VOL1
0
3.0
0
−
−
−
1.5
Vcc
0.8
V
V
V
Ii
-10
−
10
µA
Ci
tHD;STA
tLOW
tHIGH
tSU;STA
tHD;DAT
tSU;DAT
tSU;STO
−
0
4.0
4.7
4.0
4.7
10
250
4.0
−
−
−
−
−
−
−
−
−
10
100
−
−
−
−
−
−
−
pF
kHz
µs
µs
µs
µs
ns
ns
µs
tBUF
4.7
−
−
µs
15
fSCL
2006/02/16
A P
TC90L01NG
Absolute Maximum Ratings
Characteristics
Symbol
Rating
Unit
Supply voltage
VCC
11
V
Input Pin Voltage
Vin
GND - 0.3 to Vcc + 0.3
V
1250
mW
PDMAX
Power dissipation
(Note3)
Operating temperature
Topr
－20～65
°C
Storage temperature
Tstg
－55～150
°C
1250
Power consumption
PD
(mW)
Note3: When using the device at temperatures above Ta = 25°C, reduce the rated power dissipation
by 10.0 mW at TC90L01NG per degree of centigrade. (See the diagram below.)
10.0 mW/°C
850
0
0 Ambient
25 temperature
65
16
Ta (°C)
150
2006/02/16
TC90L01NG
Operating Conditions
Characteristics
Test Condition
Min
Typ.
Max
Unit
Remark
―
Supply voltage
12
8.1
9.0
9.9
V
Composite signal input amplitude
2, 4, 8

1.0

Vp-p
100IRE
Y input amplitude
4, 8

1.0

Vp-p
100IRE
Chroma input amplitude
6

286

Audio input amplitude
1, 3, 5, 7, 9, 11


3.0
mVp-p Burst
Vp-p
Electrical Characteristics
(referenced to VCC = 9 V at Ta = 25°C unless otherwise specified)
Current Consumption
Pin No.
12
Pin Name
VCC
Symbol
ICC
Test
Circuit
Min
Typ.
Max
Unit

20
34
48
mA
17
2006/02/16

TC90L01NG
Pin Voltage
Pin No.
Pin Name
Symbol
Test
Circuit
Min
Typ.
Max
Unit
1
TV-L in
V1

4.3
4.5
4.7
V
2
TV-V in
V2

4.1
4.3
4.5
V
3
TV-R in
V3

4.3
4.5
4.7
V
4
V2-V/Y in
V4

4.1
4.3
4.5
V
5
V1-L in
V5

4.3
4.5
4.7
V
6
V1-C in
V6

4.1
4.3
4.5
V
7
V1-R in
V7

4.3
4.5
4.7
V
8
V2-V in
V8

4.1
4.3
4.5
V
9
V2-L in
V9

4.3
4.5
4.7
V
10
ALC
V10


5.0

V
11
V2-R in
V11

4.3
4.5
4.7
V
12
VCC
V12


9.0

V
15
GND
V15


0

V
16
TV-R out
V16

4.0
4.5
5.0
V
17
TV-L out
V17

4.0
4.5
5.0
V
18
Y out
V18

4.0
4.3
4.6
V
19
I/O-1
V19




V
20
C out
V20

4.0
4.3
4.6
V
21
I/O-2
V21




V
22
V out
V22

4.0
4.3
4.6
V
23
Mon-R out
V23

4.2
4.5
4.8
V
24
Mon-L out
V24

4.2
4.5
4.8
V
18
2006/02/16
TC90L01NG
DC Characteristics
Characteristics
Measured Pin
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
TV-V in
R2

20
30
40
kΩ
V1-V/Y in
R4

20
30
40
kΩ
V2-V in
R8

20
30
40
kΩ
V1-C in
R6

20
30
40
kΩ
TV-L in
R1

80
120
160
kΩ
TV-R in
R3

80
120
160
kΩ
V1-L in
R5

80
120
160
kΩ
V1-R in
R7

80
120
160
kΩ
V2-L in
R9

80
120
160
kΩ
V2-R in
R11

80
120
160
kΩ
V out
R22

30
50
80
Ω
Y out
R18

30
50
80
Ω
C out
R20

30
50
80
Ω
TV-L out
R17

30
50
80
Ω
TV-R out
R16

30
50
80
Ω
Measure a voltage
change ∆V on each
pin when a current of
100 µA flows into the
pin. Then calculate the
output
resistance
value R.
Mon-L out
R24

30
50
80
Ω
R = ∆V/100 µA [Ω]
Mon-R out
R23

30
50
80
Ω
V1-C in
VthC1

2.0
2.5
3.0
V
Voltage on pin 6 at
which
data
B30
changes.
I/O 1
VthI1

2.5
3.0
3.5
V
High-Low
threshold
level of I/O-1 input (pin
19).
I/O 2
VthI2

2.5
3.0
3.5
V
High-Low
threshold
level of I/O-2 input (pin
21).
Input pin
Input resistance
Output pin
Output resistance
S mode discrimination voltage
ADC
input
voltage
discrimination
19
Remark
Measure a change ∆I
in the current flowing
into each pin when the
voltage is raised by
0.5V. Then calculate
the input resistance
value R.
R = 0.5 V/∆I [Ω]
2006/02/16
TC90L01NG
AC Characteristics
Characteristics
V out
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
TV-V in
VDR2V1

1.5


Vp-p
V1-V/Y in
VDR4V1

1.5
.

Vp-p
Input dynamic range
V out
Test Method
(1) Apply a 15 kHz
sine wave to each
input pin.
(2) In each select
mode, measure an
input amplitude at
which the output
waveform on pin
22 begins to be
distorted.
V2-V in
VDR8V1

1.5


Vp-p
V2-C in
VDR6V1

1.5


Vp-p
TV-V in
G2V1

5.5
6.0
6.5
dB
V1-V/Y in
G4V1

5.5
6.0
6.5
dB
(1) Apply a 15 kHz,
1.0 Vp-p sine wave
to each input pin.
V2-V in
G8V1

5.5
6.0
6.5
dB
(2) In each select
mode, find the gain
between input and
output.
V2-C in
G6V1

5.5
6.0
6.5
dB
TV-V in
F2V1

15


MHz
Gain
(1) Apply a 1.0 Vp-p
sine wave to each
input pin.
V out
V1-V/Y in
F4V1

15


MHz
Frequency response
V2-V in
F8V1

15


MHz
V2-C in
F6V1

15


MHz
TV-V in
CT2V1

60
70

dB
(2) In each select
mode, measure a
frequency at which
the output
amplitude on pin
22 is 3dB down
from the 15 kHz
applied level.
(1) Apply a 3.58 MHz,
1.0 Vp-p sine wave
to each input pin.
V out
V1-V/Y in
CT4V1

60
70

dB
Crosstalk
V2-V in
CT8V1

60
70

dB
V2-C in
CT6V1

60
70

dB
20
(2) In each select
mode, compare
signal output from
the selected pin
with leakage
components from
nonselected pins
to find a crosstalk.
2006/02/16
TC90L01NG
Characteristics
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
Test Method
TV-V in
VDR2Y

3.0
4.0

Vp-p
(1) Apply a 15 kHz
sine wave to each
input pin.
V1-V/Y in
VDR4Y

3.0
4.0

Vp-p
V2-V in
VDR8Y

3.0
4.0

Vp-p
TV-V in
G2Y

-0.5
0
0.5
dB
Y out
Input dynamic range
Y out
V1-V/Y in
G4Y

-0.5
0
0.5
dB
V2-V in
G8Y

-0.5
0
0.5
dB
TV-V in
F2Y

15


MHz
V1-V/Y in
F4Y

15


MHz
V2-V in
F8Y

15


MHz
TV-V in
CT2Y

60
70

dB
V1-V/Y in
CT4Y

60
70

dB
V2-V in
CT8Y

60
70

dB
Gain
Y out
Frequency response
Y out
Crosstalk
21
(2) In each select
mode, measure
an input
amplitude at
which the output
waveform on pin
18 begins to be
distorted.
(1) Apply a 15 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode, find the gain
between input and
output.
(1) Apply a 1.0 Vp-p
sine wave to each
input pin.
(2) In each select
mode, measure a
frequency at which
the output
amplitude on pin
18 is 3dB down
from the 15 kHz
applied level.
(1) Apply a 3.58 MHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode, compare
signal output from
the selected pin
with leakage
components from
nonselected pins
to find a crosstalk.
2006/02/16
TC90L01NG
Characteristics
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
TV-V in
VDR2C

1.5
2.0

Vp-p
V1-V/Y in
VDR4C

1.5
2.0

Vp-p
Test Method
(1) Apply a 3.58MHz
sine wave to each
input pin.
C out
Input dynamic range
C out
(2) In each select
mode, measure an
input amplitude at
which the output
waveform on pin
20 begins to be
distorted.
V2-V in
VDR8C

1.5
2.0

Vp-p
V2-C in
VDR6C

1.5
2.0

Vp-p
TV-V in
G2C

-0.5
0
0.5
dB
V1-V/Y in
G4C

-0.5
0
0.5
dB
(1) Apply a 15 kHz,
1.0 Vp-p sine wave
to each input pin.
V2-V in
G8C

-0.5
0
0.5
dB
(2) In each select
mode, find the gain
between input and
output.
V2-C in
G6C

-0.5
0
0.5
dB
TV-V in
F2C

15


MHz
Gain
V1-V/Y in
F4C

15


MHz
V2-V in
F8C

15


MHz
V2-C in
F6C

15


MHz
TV-V in
CT2C

60
70

dB
C out
Frequency response
V1-V/Y in
CT4C

60
70

dB
V2-V in
CT8C

60
70

dB
V2-C in
CT6C

50
55

dB
C out
Crosstalk
22
(1) Apply a 1.0 Vp-p
sine wave to each
input pin.
(2) In each select
mode, measure a
frequency at which
the output
amplitude on pin
20 is 3dB down
from the 15 kHz
applied level.
(1) Apply a 3.58 MHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode, compare
signal output from
the selected pin
with leakage
components from
nonselected pins
to find a crosstalk.
2006/02/16
TC90L01NG
Characteristics
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
Test Method
TV-L in
VDR1L1

3.0
5.0

Vp-p
(1) Apply a 1 kHz
sine wave to
each input pin.
V1-L in
VDR5L1

3.0
5.0

Vp-p
V2-L in
VDR9L1

3.0
5.0

Vp-p
TV-L in
G1L1

4.0
6.0
8.0
dB
V1-L in
G5L1

4.0
6.0
8.0
dB
V2-L in
G9L1

4.0
6.0
8.0
dB
TV-L in
VOL1L1

1.1
1.6
2.1
Vp-p
V1-L in
VOL5L1

1.1
1.6
2.1
Vp-p
TV-L out
Input dynamic range
TV-L out
Gain
TV-L out
Output level
V2-L in
VOL9L1

1.1
1.6
2.1
Vp-p
(2) In each select
mode, measure an
input amplitude at
which the output
waveform on pin
17 begins to be
distorted.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode, find the
gain between
input and output.
(3) ALC:Off
(1) Apply a 1 kHz,
2.0 Vp-p sine wave
to each input pin.
Vol:7F
(2) In each select
mode, measure an
output amplitude at
pin 17.
(3) ALC:”1.6Vp-p”
＊
GANL1

-4.0
-3.0
-2.0
dB
TV-L out
Vol:7F
ALC level Min.
ALC level Max.
(1) Set ALC level
“1.1Vpp” and
measure output
level changes.
＊
GAXL1

2.0
3.0
4.0
dB
(2) Set ALC level
“2.3Vpp” and
measure output
level changes.
Vol:7F
TV-L in
F1L1

0.1


MHz
V1-L in
F5L1

0.1


MHz
V2-L in
F9L1

0.1


MHz
TV-L in
CT1L1

70
80

dB
TV-L out
Frequency response
TV-L out
23
(1) Apply a 1.0 Vp-p
sine wave to each
input pin.
(2) In each select
mode, measure a
frequency at which
the output amplitude
on pin 17 is 3dB
down from the 1 kHz
applied level.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
2006/02/16
TC90L01NG
Characteristics
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
Crosstalk
V1-L in
CT5L1

70
80

dB
V2-L in
CT9L1

70
80

dB
TV-L in
M1L1

70
90

dB
V1-L in
M5L1

70
90

dB
V2-L in
M9L1

70
90

dB
TV-L out
Mute attenuation
24
Test Method
mode, compare
signal output from
the selected pin
with leakage
components from
nonselected pins
to find a crosstalk.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode, compare
the output
amplitudes on pin
17 when mute is
turned on and
turned off to find
mute attenuation.
2006/02/16
TC90L01NG
Characteristics
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
Test Method
TV-R in
VDR3R1

3.0
5.0

Vp-p
(1) Apply a 1 kHz
sine wave to
each input pin.
V1-R in
VDR7R1

3.0
5.0

Vp-p
V2-R in
VDR11R1

3.0
5.0

Vp-p
TV-R in
G3R1

4.0
6.0
8.0
dB
V1-R in
G7R1

4.0
6.0
8.0
dB
V2-R in
G11R1

4.0
6.0
8.0
dB
TV-R in
VOL3R1

1.1
1.6
2.1
Vp-p
V1-R in
VOL7R1

1.1
1.6
2.1
Vp-p
TV-R out
Input dynamic range
TV-R out
Gain
TV-R out
Output level
V2-R in
VOL11R1

1.1
1.6
2.1
Vp-p
(2) In each select
mode, measure an
input amplitude at
which the output
waveform on pin
16 begins to be
distorted.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode, find the
gain between
input and output.
(3) ALC:Off
(1) Apply a 1 kHz,
2.0 Vp-p sine wave
to each input pin.
Vol:7F
(2) In each select
mode, measure an
output amplitude at
pin 16.
(3) ALC:”1.6Vp-p”
＊
GANR1

-4.0
-3.0
-2.0
dB
TV-R out
Vol:7F
ALC level Min.
ALC level Max.
(1) Set ALC level
“1.1Vpp” and
measure output
level changes.
＊
GAXR1

2.0
3.0
4.0
dB
(2) Set ALC level
“2.3Vpp” and
measure output
level changes.
Vol:7F
TV-R in
F3R1

0.1


MHz
V1-R in
F7R1

0.1


MHz
V2-R in
F11R1

0.1


MHz
TV-R in
CT3R1

70
80

dB
TV-R out
Frequency response
TV-R out
Crosstalk
25
(1) Apply a 1.0 Vp-p
sine wave to each
input pin.
(2) In each select
mode, measure a
frequency at which
the output
amplitude on pin
16 is 3dB down
from the
1 kHz applied
level.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
2006/02/16
TC90L01NG
Characteristics
TV-R out
Mute attenuation
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
V1-R in
CT7R1

70
80

dB
V2-R in
CT11R1

70
80

dB
TV-R in
M3R1

70
90

dB
V1-R in
M7R1

70
90

dB
V2-R in
M11R1

70
90

dB
26
Test Method
mode, compare
signal output from
the selected pin
with leakage
components from
nonselected pins
to find a crosstalk.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode, compare
the output
amplitudes on pin
16 when mute is
turned on and
turned off to find
mute attenuation.
2006/02/16
TC90L01NG
Characteristics
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
TV-L in
VDR1L2

3.5
5.0

Vp-p
V1-L in
VDR5L2

3.5
5.0

Vp-p
V2-L in
VDR9L2

3.5
5.0

Vp-p
TV-L in
G1L2

-0.5
0
0.5
dB
V1-L in
G5L2

-0.5
0
0.5
dB
V2-L in
G9L2

-0.5
0
0.5
dB
TV-L in
F1L2

0.1


MHz
V1-L in
F5L2

0.1


MHz
V2-L in
F9L2

0.1


MHz
TV-L in
CT1L2

70
90

dB
V1-L in
CT5L2

70
90

dB
V2-L in
CT9L2

70
90

dB
TV-L in
M1L2

70
80

dB
V1-L in
M5L2

70
80

dB
V2-L in
M9L2

70
80

dB
Mon-L out
Input dynamic range
Mon-L out
Gain
Mon-L out
Frequency response
Mon-L out
Crosstalk
Mon-L out
Mute attenuation
27
Test Method
(1) Apply a 1 kHz
sine wave to
each input pin.
(2) In each select
mode, measure
an
input
amplitude
at
which the output
waveform on pin
24 begins to be
distorted.
(1) Apply a 1 kHz,
1.0 Vp-p sine
wave to each
input pin.
(2) In each select
mode, find the gain
between input and
output.
(1) Apply a 1.0 Vp-p
sine wave to each
input pin.
(2) In each select
mode, measure a
frequency at which
the
output
amplitude on pin
24 is 3dB down
from the 1 kHz
applied level.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode,
compare
signal output from
the selected pin
with
leakage
components from
nonselected pins
to find a crosstalk.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode,
compare
the
output
amplitudes on pin
24 when mute is
turned on and
turned off to find
mute attenuation.
2006/02/16
TC90L01NG
Characteristics
Select Mode
Symbol
Test
Circuit
Min.
Typ.
Max.
Unit
Test Method
TV-R in
VDR3R2

3.5
5.0

Vp-p
(1) Apply a 1 kHz sine
wave to each input
pin.
V1-R in
VDR7R2

3.5
5.0

Vp-p
V2-R in
VDR11R2

3.5
5.0

Vp-p
TV-R in
G3R2

-0.5
0
0.5
dB
V1-R in
G7R2

-0.5
0
0.5
dB
V2-R in
G11R2

-0.5
0
0.5
dB
TV-R in
F3R2

0.1


MHz
V1-R in
F7R2

0.1


MHz
V2-R in
F11R2

0.1


MHz
TV-R in
CT3R2

70
90

dB
V1-R in
CT7R2

70
90

dB
V2-R in
CT11R2

70
90

dB
TV-R in
M3R2

70
80

dB
V1-R in
M7R2

70
80

dB
V2-R in
M11R2

70
80

dB
Mon-R out
Input dynamic range
Mon-R out
Gain
Mon-R out
Frequency response
Mon-R out
Crosstalk
Mon-R out
Mute attenuation
28
(2) In each select
mode, measure
an
input
amplitude
at
which the output
waveform on pin
23 begins to be
distorted.
(1) Apply a 1 kHz,
1.0 Vp-p sine
wave to each
input pin.
(2) In each select
mode, find the gain
between input and
output.
(1) Apply a 1.0 Vp-p
sine wave to each
input pin.
(2) In each select
mode, measure a
frequency at which
the
output
amplitude on pin
23 is 3dB down
from the 1 kHz
applied level.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode,
compare
signal output from
the selected pin
with
leakage
components from
nonselected pins
to find a crosstalk.
(1) Apply a 1 kHz,
1.0 Vp-p sine wave
to each input pin.
(2) In each select
mode,
compare
the
output
amplitudes on pin
23 when mute is
turned on and
turned off to find
mute attenuation.
2006/02/16
TC90L01NG
Reference data
ALC characteristic
1.1Vp-p
1.6Vp-p
2.3Vp-p
Off
3
Output Level (Vp-p)
2.5
2
1.5
1
0.5
0
0
1
2
3
Input Level (Vp-p)
4
5
6
Audio Volume characteristic
10
TV-L out, TV-R out (dB)
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
7
F
17
1F
27
2F
37
3F
47
4F
57
5F
67
6F
77
7F
BUS Data (VOL)
29
2006/02/16
TC90L01NG
Application Circuit
330p
1μ
10k
+
1
TV-L in
Monitor-L out
24
2
TV-V in
Monitor-R out
23
3
TV-R in
V out
22
4
V1-V/Y in
I/O 2 21
75
0.1μ
+
330p
1μ
10k
+
75
0.1μ
+
IN
OUT
4.7k
330p
1μ
10k
+
5
V1-L in
6
V1-C in
C out
0.01μ
20
75
0.01μ
+
IN
I/O 1 19
OUT
4.7k
330p
1μ
10k
+
7
V1-R in
Y out
18
8
V2-V in
TV-L out
17
9
V2-L in
TV-R out
16
GND
15
14
0.01μ
75
0.1μ
+
330p
1μ
10k
+
1M
22μ
+
10 ALC
330p
1μ
10k
+
11
V2-R in
SCL
12
Vcc
SDA 13
0.01μ
100
100
+
100μ
Vcc：9V
30
2006/02/16
TC90L01NG
Test Circuit
R1：620
TP-1
TV-L
+
R2：75
1
Monitor-L out
24
TP-24
C2：10μ
+
R3：620
2
TV-V in
Monitor-R out
23
3
TV-R in
V out
22
TP-23
+
R4：75
V out
TP-4
C4：10μ
V1-V/Y
+
R5：620
4
V1-V/Y in
I/O 2 21
IN
TP-5
+
5
V1-L in
C out
R17：4.7k
OUT
TP-21
C5：1μ
V1-L
SW-6
20
C out
TP-6
TP-26
C17：0.01μ
C6：0.01μ
+
6
V1-C in
I/O 1 19
IN
R7：620
TP-7
+
R8：75
7
V1-R in
Y out
R15：4.7k
OUT
TP-19
C7：1μ
V1-R
SW-4
18
Y out
TP-8
C15：0.01μ
TP-25
C8：10μ
V2-V
+
R9：620
8
TV-L out
V2-V in
17
TV-L out
TP-9
C9：1μ
V2-L
+
9
V2-L in
TV-R out
16
TV-R out
TP-10
R11：1M
10 ALC
GND
15
11
SCL
14
TP-11
C11：22μ
+
R12：600
V2-R
C19：0.01μ
TP-3
C3：1μ
TV-R
R6：75
TV-L in
TP-2
TV-V
V1-C
C20：0.01μ
C1：1μ
C12：1μ
V2-R in
SCL
TP-12
+
C13：0.01μ
R14：100
12
Vcc
SDA
13
TP-14
R13：100
SDA
TP-13
+
C14：100μ
Vcc：9V
31
2006/02/16
TC90L01NG
Package Dimensions
Weight: 1.22 g (typ.)
32
2006/02/16
TC90L01NG
About solderability, following conditions were confirmed.
･Solderability
(1) Use of Sn-37Pb solder Bath
・solder bath temperature = 230℃
・dipping time = 5 seconds
・the number of times = once
・use of R-type flux
(2) Use of Sn-3.0Ag-0.5Cu solder
・solder bath temperature = 245℃
・dipping time = 5 seconds
・the number of times = once
use of R-type flux
RESTRICTIONS ON PRODUCT USE
030619EBA
The information contained herein is subject to change without notice.
The information contained herein is presented only as a guide for the applications of our products. No responsibility
is assumed by TOSHIBA for any infringements of patents or other rights of the third parties which may result from
its use. No license is granted by implication or otherwise under any patent or patent rights of TOSHIBA or others.
TOSHIBA is continually working to improve the quality and reliability of its products. Nevertheless, semiconductor
devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical
stress. It is the responsibility of the buyer, when utilizing TOSHIBA products, to comply with the standards of safety
in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such
TOSHIBA products could cause loss of human life, bodily injury or damage to property.
In developing your designs, please ensure that TOSHIBA products are used within specified operating ranges as
set forth in the most recent TOSHIBA products specifications. Also, please keep in mind the precautions and
conditions set forth in the “Handling Guide for Semiconductor Devices,” or “TOSHIBA Semiconductor Reliability
Handbook” etc..
The TOSHIBA products listed in this document are intended for usage in general electronics applications (computer,
personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.).
These TOSHIBA products are neither intended nor warranted for usage in equipment that requires extraordinarily
high quality and/or reliability or a malfunction or failure of which may cause loss of human life or bodily injury
(“Unintended Usage”). Unintended Usage include atomic energy control instruments, airplane or spaceship
instruments, transportation instruments, traffic signal instruments, combustion control instruments, medical
instruments, all types of safety devices, etc.. Unintended Usage of TOSHIBA products listed in this document shall
be made at the customer’s own risk.
The products described in this document are subject to the foreign exchange and foreign trade laws.
TOSHIBA products should not be embedded to the downstream products which are prohibited to be produced and
sold, under any law and regulations.
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2006/02/16