Rohm BU1424K Ntsc / pal digital rgb encoder Datasheet

Multimedia ICs
NTSC / PAL digital RGB encoder
BU1424K
The BU1424K is an IC that converts digital RGB / YUV input to composite (NTSC / PAL / PAL60), luminance (Y),
and chrominance (C) signals, and outputs the results.
Applications
•Video
interfaces for VIDEO-CDs and CD-G decoders
•1)Features
Input clocks supported.
27.0 / 13.5MHz
28.636 / 14.318MHz
28.375 / 14.1875MHz
35.4695 / 17.73475MHz
2) 24-bit RGB and 16-bit YUV input signals are supported.
3) Both master and slave systems are supported.
4) 9-bit high-speed DAC is used for DAC output of
composite VIDEO, Y, and C signals.
5) Internal 8-color OSD output function is provided.
6) FSC-TRAP on the Y channel can be turned on and
off.
7) C channel is equipped with an internal chrominance
band-pass filter in addition to the U,V. low-pass filter.
8) 5V single power supply, low power consumption.
(0.4W typ.)
9) Y and C output can be turned off (the power consumption with Y and C off is 0.25W typ.).
1
Multimedia ICs
BU1424K
OSDSW
BOSD
GOSD
ROSD
•Block diagram
RGB 24BITS
OSD PALLET
RD
GD / Y
LATCH
Y-FILTER
Y-LEVEL SHIFT
RGB
to
YUV
CHROMA GEN
UV
FILTER
BD / UV
MIX SIG
and
sync
burst
C-FILTER
DAC
V
VOUT
Y
YOUT
C
COUT
VOLK
RSTB
PIXCLK
VIDEO TIMING CONTROL
SYNC BLANK
HSY
SUB CARRIER BURST GENERATOR
BURST
VSY
BCLK
2
CLKSW
NTB
PAL60B
CDGSWB
G4FSC
YFILONB [1.0]
IM [0.1]
INT
ADDH
TEST1,2
MODE CONTROL FIELD / FLAME CONTROL
Multimedia ICs
BU1424K
•Pin descriptions
Pin No. Pin name
Function
Function
Pin No. Pin name
∗1
1
BOSD
OSD BLUE DATA INPUT
33
SLABEB
2
GD0 / Y0
GREEN DATA Bit0 (LSB)
34
ADDH
3
GD1 / Y1
GREEN DATA Bit1
35
VREF-C
4
GD2 / Y2
GREEN DATA Bit2
36
CGND
CHROMA OUTPUT GROUND
5
GD3 / Y3
GREEN DATA Bit3
37
COUT
CHROMA OUTPUT
6
GD4 / Y4
GREEN DATA Bit4
38
VGND
Composite Output Ground
7
GD5 / Y5
GREEN DATA Bit5
39
VOUT
COMPOSITE OUTPUT
8
GD6 / Y6
GREEN DATA Bit6
40
AVSS
Analog Ground (DAC. VREF)
9
GND
DIGITAL GROUND
41
AVDD
ANALOG (DAC) VDD
GREEN DATA Bit7 (MSB)
10
GD7 / Y7
SELECT MASTER / SLAVE
+ 0.5 / – 0.5LINE at NON-INTER
DAC BIAS
42
IR
11
BD0 / UV0 BLUE DATA Bit0 (LSB)
43
AVDD
12
BD1 / UV1 BLUE DATA Bit1
44
YGND
Luminance Output Ground
13
BD2 / UV2 BLUE DATA Bit2
45
YOUT
Luminance Output
14
BD3 / UV3 BLUE DATA Bit3
C4FSC
4FSC / 3.2FSC at PALCD-G
15
OSDSW
OSD ENABLE / DISABLE
46
∗1
47
REFERENCE RESISTOR
ANALOG (VREF) VDD
YFILON2B Y-FILSEL THROU / FILON2
16
CDGSWB SELECT Video-CD / CD-G
48
17
BD4 / UV4 BLUE DATA Bit4
49
18
BD5 / UV5 BLUE DATA Bit5
50
19
BD6 / UV6 BLUE DATA Bit6
51
VCLK
Video Clock Input
20
BD7 / UV7 BLUE DATA Bit7 (MSB)
52
RSTB
NORMAL / RESET
YCOFF
DAC (YOUT. COUT) OFF
YFILON1B Y-FILSEL THROU / FILON1
PAL60B
NORMAL / PAL60 at PALMODE
21
GND
DIGITAL GROUND
53
CLKSW
SEL × 1CLK / × 2CLK
22
NTB
SELECT NTSC / PAL MODE
54
RD0
RED DATA Bit0 (LSB)
23
IM0
SELECT YUV / RGB
55
RD1
RED DATA Bit1
24
IM1
SELECT DAC / NORMAL
56
RD2
RED DATA Bit2
25
TEST1
Normally pull down to GND
57
ROSD
26
TEST2
SELECT U / V TIMING
58
RD3
RED DATA Bit3
∗1
∗1
∗1
∗1
∗1
∗1
OSD RED DATA INPUT
27
VSY
V-SYNC INPUT or OUTPUT
59
RD4
RED DATA Bit4
28
HSY
H-SYNC INPUT or OUTPUT
60
RD5
RED DATA Bit5
29
PIXCLK
1 / 2freq. of BCLK
61
VDD
DIGITAL VDD
30
BCLK
INTERNAL CLOCK OUTPUT
62
RD6
RED DATA Bit6
31
VDD
DIGITAL VDD
63
RD7
RED DATA Bit7
32
INT
Interlace / Non-Interlace
64
GOSD
OSD GREEN DATA INPUT
∗1
∗2
∗
∗2
∗2
∗2
∗1
∗1
∗1
∗1
∗1
∗1
∗1
∗1
∗1
∗1
∗1 Internal pull-down resistor
∗2 Internal pull-up resistor
3
Multimedia ICs
BU1424K
•Absolute maximum ratings (Ta = 25°C)
Parameter
Applied voltage
Symbol
Limits
Unit
VDD, AVDD
– 0.5 ~ + 7.0
V
Input voltage
Storage temperature
– 0.5 ~ VDD + 0.5
V
Tstg
– 55 ~ + 150
°C
Pd
1350∗1
mW
VIN
Power dissipation
∗1 Reduced by 11mW for each increase in Ta of 1°C over 25°C.
When mounted on a 120mm × 140mm × 1.0mm glass epoxy board.
∗ Operation is not guaranteed at this value.
䊊 Not designed for radiation resistance.
•Recommended operating conditions (Ta = 25°C)
Parameter
Power supply voltage
Symbol
VDD
= AVDD∗
Limits
Unit
+ 4.75 ~ + 5.25
V
Input high level voltage
VIH
Input low level voltage
VIL
0 ~ + 0.8
V
Analog input voltage
VAIN
0 ~ AVDD
V
Operating temperature
Topr
+ 2.1 ~ VDD
V
°C
– 25 ~ + 60
∗ Should be used at VDD = AVDD.
otherwise noted, Ta = 25°C, V
•Electrical characteristics (unless
YGND)
DD
= AVDD = 5.0V, GND = AVSS = VGND = CGND =
Digital block
Parameter
Symbol
Min.
Typ.
Max.
Unit
Conditions
Burst frequency 1
fBST1
—
3.57954
—
MHz
—
Burst frequency 2
fBST2
—
4.43361
—
MHz
—
Burst cycle
CBST
—
9
—
CYC
Operating circuit current 1
Idd1
—
80
—
mA
27MHz color bar
Operating circuit current 2
Idd2
—
40
—
mA
27MHz color bar PD mode
Output high level voltage
VOH
4.0
4.5
—
V
IOH = – 2.0mA
Output low level voltage
VOL
—
0.5
1.0
V
IOH = 2.0mA
Input high level voltage
VIH
2.1
—
—
V
—
Input low level voltage
VIL
—
—
0.8
V
—
Input high level current
IIH
– 10
0.0
10.0
µA
—
Input low level current
IIL
– 10
0.0
10.0
µA
—
—
DAC block
Parameter
DAC resolution
Symbol
Min.
Typ.
Max.
Unit
Conditions
RES
—
9
—
BITS
—
EL
—
± 0.5
Y white level current
IYW
—
25.14
—
mA
—
Y black level current
IYB
—
7.24
—
mA
—
Y zero level current
IYZ
– 10
0.0
10.0
µA
—
V white level current
IYW
—
25.14
—
mA
—
V black level current
IYB
—
7.24
—
mA
—
V zero level current
IYZ
– 10
0.0
10.0
µA
—
Linearity error
4
± 3.0
LSB
IR = 1.2kΩ
BOSD
GD0
1
2
0 1 2
CDGSWB
OSDSW
15
16
BD3
14
BD2
BU1424K
37
36
35
34
33
CGND
VREF
ADDH
SLABEB
41
38
42
IR
AVDD
COUT
43
AVDD
VGND
44
YGND
40
45
YOUT
39
46
G4FSC
VOUT
47
AVSS
48
YCOFF
YFILON2B
INT
VDD
BCLK
PIXCLK
HSY
VSY
TEST2
TEST1
IM1
IM0
NTB
GND
BD7
BD6
BD5
BD4
7
3
20
19
18
17
INTERLACE / NON-INTER
PAL / NTSC
5 6
13
4
BD1
3
BD0
0 1 2
12
64
YFILON1B
PAL GOB
VCLK
RSTB
CLKSW
RD0
RD1
RD2
ROSD
RD3
RD4
RD5
VDD
RD6
RD7
GOSD
11
63
GD7
6
7
62
10
61
GND
60
9
59
GD6
58
GD5
57
8
3
4
5
7
56
GD4
55
6
54
GD3
0
1
2
5
53
GD2
52
GD1
51
4
50
3
Reset [Low active] in
49
Video-CD / CD-C
OSD in
[Red]
OSD in [Green]
[Blue]
OSD in
OSD enable
R Data 0...7
G Data 0...7
B Data 0...7
Y-filter select
Pixel Clock in
0.01µF
1.2k
Hsync out
Vsync out
OSD CLOCK
75
75
75
Chrominance
Composite
Luminance
Multimedia ICs
BU1424K
example
•(1)Application
Example in Master mode: Doubled clock is input and 24-bit RGB input is used
32
31
30
29
28
27
25
26
24
23
22
21
7
6
5
4
Fig.1
5
6
BOSD
GD0
1
2
5 6
Fig.2
0 1 2
CDGSWB
16
35
34
33
VREF
SLABEB
36
ADDH
37
CGND
41
38
42
IR
AVDD
COUT
43
AVDD
VGND
44
YGND
40
45
YOUT
39
46
G4FSC
VOUT
47
AVSS
48
YCOFF
YFILON2B
INT
VDD
BCLK
PIXCLK
HSY
VSY
TEST2
TEST1
IM1
IM0
NTB
GND
BD7
BD6
BD5
BD4
7
3
20
19
18
17
Vsync in
Hsync in
OSDSW
15
BU1424K
PAL / NTSC
INTERLACE / NON-INTER
BD3
14
BD2
4
13
3
BD1
0 1 2
BD0
64
12
63
11
62
GD7
6
7
10
61
GND
60
9
59
GD6
58
GD5
3
4
5
8
57
7
55
GD4
56
6
54
GD3
0
1
2
5
53
GD2
52
GD1
51
YFILON1B
PALGOB
YCLK
RSTB
CLKSW
RD0
RD1
RD2
ROSD
RD3
RD4
RD5
VDD
RD6
RD7
GOSD
4
50
3
49
Video-CD / CD-C
[Red]
OSD in [Green]
[Blue]
OSD in
OSD enable
OSD in
Y Data 0...7
U.V Data 0...7
Reset [Low active] in
Y-filter select
Pixel Clock in
0.01µF
1.2k
OSD CLOCK
75
75
75
Chrominance
Composite
Luminance
Multimedia ICs
BU1424K
(2) Example in Slave mode: Doubled clock is input and 16-bit YUV input is used
32
31
30
29
28
25
27
24
26
23
22
21
7
6
5
4
Multimedia ICs
BU1424K
•Equivalent circuits
Pin No.
Pin name
I/O
2~8
10
GD (7: 0)
I
G data input pin for 24-bit RGB input.
Y data input pin for 16-bit YUV input.
11 ~ 14
17 ~ 20
BD (7: 0)
I
B data input pin for 24-bit RGB input.
U, V data input pins for 16-bit YUV
input.
54 ~ 56
58 ~ 60
62.63
RD (7: 0)
I
R data input pin for 24-bit RGB input.
1
57
64
15
ROSD
GOSD
BOSD
OSDSW
I
OSD data input pin when using the
OSD function.
When the OSDSW pin is HIGH, input
to the ROSD, GOSD, and BOSD pins
takes precedence over RGB, and the
data is converted.
23
24
IM0
IM1
I
Control pins used to select RGB (24bit), YUV (16-bit) or DAC Through as
the input mode.
16
CDGSWB
I
Switches the mode between VideoCD (HIGH) and CD-G (LOW).
22
NTB
I
Switches the mode between NTSC
(LOW) and PAL (HIGH).
I/O
This is the horizontal synchronization
signal pin. Negative polarity HSYNC
signals are input (when SLABEB =
LOW) or output (when SLABEB =
HIGH) here. This is also used as the
synchronization signal for fixing the
PIXCLK output phase.
28
HSY
Equivalent circuit
Function
7
Multimedia ICs
Pin No.
Pin name
I/O
27
VSY
I
Vertical synchronization signals
(VSYNC) are input (when SLABEB =
LOW) or output (when SLABEB =
HIGH) here.
O
The internal processing clock is divided in half and then output. Data is
read at the point at which the edge of
this clock changes. This can also be
used as the clock for the OSD IC.
I
This pin switches between interlace
(when HIGH) and non-interlace
(when LOW) modes. This pin is effective in both the VIDEO-CD and CD-G
modes.
29
32
8
BU1424K
PIXCLK
INT
Equivalent circuit
Function
33
34
SLABEB
ADDH
I
I
This pin switches between the Master
(when HIGH) and Slave (when LOW)
modes. It is effective in the noninterlace mode, and it switches between – 0.5 lines (when LOW) and +
0.5 lines (when HIGH) for the number
of lines in an interlace field.
35
Vref-C
I
This is the reference voltage generator
circuit monitoring pin which determines the output amplitude (output current for 1 LSB) of the DAC.
Multimedia ICs
BU1424K
Pin No.
Pin name
I/O
37
COUT
O
This is the chrominance output pin for
the S pin.
39
VOUT
O
Composite output pin.
45
YOUT
O
Luminance output pin for the S pin.
I
The output amplitude (output current
for 1 LSB) of the DAC is specified
using an external resistor, and this pin
controls the value of the current flowing per bit.
I
When there is HIGH input at the signal
input pin, which switches to and from
the low power consumption mode, this
turns off the output from the YOUT
and COUT pins.
O
Output for the internal clock.
When CLKSW is HIGH, the VCLK buffer output.
When CLKSW is LOW, the VCLK 1 / 2
cycle output.
42
48
30
IR
YCOFF
BCLK
Equivalent circuit
Function
9
Multimedia ICs
Pin No.
Pin name
I/O
51
VCLK
I
Input pin for the reference clock in the
Video-CD mode.
52
RSTB
I
Reset input pin which initializes the
system.
49
YFILON1B
YFILON2B
I
Selects the F characteristic of the
Y-FILTER. However, this is only effective when OSDSW is LOW.
I
Switches between the PAL and
PAL60 modes. This is effective only
when the NTB pin is HIGH. (PAL
mode only).
50
10
BU1424K
PAL60B
Equivalent circuit
Function
53
CLKSW
I
This switches between dividing the
VCLK input in half and using it as an
internal clock (when LOW), and using
it as an internal clock without dividing
it in half (when HIGH).
46
G4FSC
I
Switching pin for CDG mode input frequency 14.1875 / 4fsc.
25
26
TEST1
TEST2
I
Normally, this is connected to the
GND pin. However, when 16-bit YUV
input is used, the TEST2 pin can be
used as the U and V timing control
pins.
Multimedia ICs
BU1424K
Pin No.
Pin name
I/O
Equivalent circuit
Function
31
61
41
43
VDD
AVDD
—
—
Power supply pin for the digital, the
analog and blocks.
9
21
36
38
40
44
GND
CGND
VGND
AVSS
YGND
—
—
Ground for digital and analog blocks.
11
Multimedia ICs
BU1424K
operation
•(1)Circuit
Overview
including black) chrominance data. At the same time, a
clock with a frequency half that of the internal clock is
output from the PIXCLK pin. As a result, the PIXCLK
pin can easily be directly connected to the OSD IC
clock input pin, and the OSDSW pin can be directly
connected to the BLK output pin. Thus, the BU1424K
and the OSD IC can be synchronized, and OSD text
with a burster trimmer stacker feature can be used.
If the input data is in the RGB format, it is converted to
YUV. If it is in the YUV format, it is converted from the
CCIR-601 format to level-shifted YUV data. The YUV
data is then adjusted to the 100IRE level in the NTSC,
PAL, and PAL60 modes, and U and V data is phaseadjusted by a sub-carrier generated internally, and is
modulated to chrominance signals.
Ultimately, elements such as the necessary synchronization level, the color blanking level, and burst signals are mixed, and pass through the 9-bit DAC to be
output as NTSC or PAL composite signals, luminance
signals, and chrominance signals (conforming to RS170A). At this point, the DAC is operating at twice the
internal clock, making it possible to reduce the number
of attachments.
Furthermore, luminance signal output and chrominance
signal output can be turned off. At this point, it is possible to reduce the level of power consumption.
The DAC output is current output. If a resistor of a
specified value is connected to the IR pin, 2.0VP-P output can be obtained by connecting 75Ω to the VOUT
pin as an external resistor. As a result, normally, when
a video input pin (75Ω terminus) is connected, the output is approximately 1.0VP-P voltage output at a white
100% level.
The BU1424K converts digital images and video data
with an 8-bit configuration to 9-bit composite signals
(VOUT), luminance signals (YOUT), and chrominance
signals (COUT) for the NTSC, PAL, and PAL60 formats, and outputs the converted data as analog TV
signals.
The user may select whether VOUT consists of chrominance signals that have passed through a chrominance
band pass and luminance signals that have been
mixed, or luminance signals that have passed through
a chrominance trap and luminance signals that have
not passed through a chrominance trap. The F characteristic of this chrominance trap may be selected from
among three available types. Since YOUT normally
does not pass through the trap, it is optimum for the S
pin. COUT normally passes through the chrominance
band pass, and is thus highly resistance to dot interference. In addition, when used in the doubled clock
mode, it passes through an interpolator filter, and for
that reason is able to reproduce even cleaner image
quality.
A correspondence can be set up between input digital
image data and Video-CD and CD-G decoder output.
Output TV signals, in addition to switching among the
NTSC, PAL, and PAL60 modes, can be switched between the interlace and non-interlace modes.
The data clock input to the VCLK pin can also be input
as a doubled clock for the data rate (in doubled clock
modes). In doubled clock modes, data is read and
processed at the rising edge of an internal clock that
has been divided in half. In ordinary clock modes, data
is read and processed at the rising edge of the clock
that has the same phase as the input clock. Two input
data formats are supported: 24-bit RGB (4: 4: 4) and
16-bit YUV (4: 2: 2). These are input to RD0 to 7, GD0
to 7, and BD0 to 7, respectively. The selected input format can be switched using the IM0 and IM1 pin input.
When the OSDSW pin is set to the "Enabled" (H) state,
data input to the ROSD, GOSD, and BOSD pins becomes effective, making it possible to input 7-color (8
(2) Specifying the mode
1) Power saving mode
With the BU1424K, setting the YCOFF pin to HIGH
turns off the output from the YOUT and COUT pins of
the DAC output, enabling use in the low power consumption mode.
Table 1: Low power consumption mode with the YCOFF pin
Pin No.
48
12
Output mode and power consumption
Pin name
YCOFF
VOUT pin
YOUT pin
COUT pin
Power consumption (Typ.)
LOW
Composite signal
Luminance signal
Chrominance signal
0.45W
HIGH
Composite signal
No output (0V)
No output (0V)
0.25W
Multimedia ICs
BU1424K
2) Output modes
The "Video-CD" and "CD-G" modes can be supported
by both digital image and video data, with the mode
being switched by the CDGSWB pin input. When the
CDGSWB pin input is LOW, the CD-G mode is set, and
when HIGH, the Video-CD mode is set. Also, the
"NTSC", "PAL", and "PAL60" modes may be selected
as the output TV modes. The output TV mode is
switched using the NTB and PAL60 pin input. Setting
the NTB pin input to LOW sets the NTSC mode, and
setting it HIGH with the PAL60 pin also HIGH sets the
PAL mode. Setting the NTB pin HIGH and the PAL60
pin LOW, sets the PAL60 mode.
Table 2: Specifying modes
NTB
PAL60
GDGSWB
Decoder mode
TV mode
0
CD-G
NTSC
0
∗
∗
0
1
Video-CD
NTSC
1
0
0
CD-G
PAL60
1
0
1
Video-CD
PAL60
1
1
0
CD-G
PAL
1
1
1
Video-CD
PAL
Also, INT pin input can be used to switch between "interlace output" and "non-interlace output."
Setting the input to LOW enables non-interlace output,
and setting it to HIGH enables interlace output. When
non-interlace output is used, the number of lines in one
field can be controlled using the ADDH pin. If the
ADDH pin is LOW, the number of lines in one field is
set to the number of interlace output lines minus 0.5
lines, and when HIGH, the number of lines in one field
is set to the number of interlace output lines plus 0.5
lines.
Table 3: Pin settings for interlace / non-interlace modes
No. of Lines / Field
INT
ADDH
Scan Mode
0
0
Non-interlace
0
1
Non-interlace
263
313
1
∗
Interlace
262.5
312.5
3) Input formats
The digital data input format can be set as shown in the
table below, using the IM1 and IM0 pins. Both 24-bit
NTSC / PAL60
PAL
262
312
RGB (4: 4: 4) and 16-bit YUV (4: 2: 2) are supported. In
addition, digital RGB input can be output as analog
RGB output (RGB Through mode).
Table 4: Input format settings
IM1
IM0
Input format
Output signal
0
0
R (8 bits), G (8 bits), B (8 bits)
TV signals (9-bit resolution)
0
1
YUV16bit (4: 2: 2)
TV signals (9-bit resolution)
1
0
—
—
1
1
ROSD, GOSD, BOSD expanded to RGB input
RGB analog signals (9 bits)
13
Multimedia ICs
BU1424K
Table 5: Bit assignments in RGB Through mode
Output Pin
BIT8
BIT7
BIT6
BIT5
BIT4
BIT3
BIT2
BIT1
BIT0
YOUT (45)
RD7
RD6
RD5
RD4
RD3
RD2
RD1
RD0
ROSD
VOUT (39)
GD7
GD6
GD5
GD4
GD3
GD2
GD1
GD0
GOSD
COUT (37)
BD7
BD6
BD5
BD4
BD3
BD2
BD1
BD0
BOSD
The BU1424K has an internal OSD switch and chrominance data generating function. Consequently, joint
usage of an OSD-IC with blanking and R, G, and B output can be easily supported by the OSD. Moreover, a
clock with half the internal processing frequency of the
BU1424K is output from the PIXCLK pin, and can be
connected to the OSD-IC clock input, enabling the timing to be captured.
ROSD, GOSD, and BOSD pin input is effective as long
as the OSDSW pin input is HIGH. The relationship between OSD data and chrominance data is as shown in
Table 6 below.
Table 6: Correspondence between OSD function, input data and chrominance output
OSDSW
ROSD
GOSD
BOSD
Output chrominance signal
1
0
0
0
Black (blanking)
1
0
0
1
Blue
1
0
1
0
Green
1
0
1
1
Cyan
1
1
0
0
Red
1
1
0
1
Magenta
1
1
1
0
Yellow
1
1
1
1
White
0
∗
∗
∗
Based on input specified by IM0 and IM1
4) Clock modes
With the BU1424K, clock input is available at the VCLK
pin.
Clocks supplied from an external source should basically be input at a frequency double that of clocks used
internally (basic clock: BCLK) (when the CLKSW pin is
LOW). The phase relationship between the internal
clock and the external clock at this time is as shown in
Fig. 3, with the HSY pin input serving as a reference. In
the Master mode, in which data from the HSY pin is
output and used, HSY is output at the timing shown in
Fig. 3. With the BU1424K, data (RD, GD, BD, etc.) is
read at the rising edge of the internal clock (BCLK), so
data should be input to the BU1424K as shown in Fig.
3.
HSY
VCLK
Internal clock
(BCLK)
Input data
Fig.3
14
Illustration of clock timing (CLKSW is LOW)
Multimedia ICs
BU1424K
Also, setting the CLKSW pin to HIGH enables the frequency of the external clock to be used as BCLK, the
internal clock, just as it is. Since the data is read to the
BU1424K at the rising edge of BCLK at this time as
well, data should be input as shown in Fig. 4. The relationship with HSY is also as shown in Fig. 4.
HSY
VCLK
Internal clock
(BCLK)
Input data
Fig.4
Illustration of clock timing (CLKSW is HIGH)
With the BU1424K, the sub-carrier (burst) frequency is
generated using the internal clock. For this reason, the
frequencies used in the various modes are limited, so
those frequencies should be input (see Table 7 below).
Table 7: BU1424K clock input frequency settings
CD-G mode
Video-CD mode
CLKSW
pin
G4FSC
pin
Same for NTSC / PAL / PAL60
NTSC
PAL / PAL60
0
0
27.000MHz
28.636MHz
28.3750MHz
0
1
27.000MHz
28.636MHz
35.4695MHz
1
0
13.500MHz
14.318MHz
14.1875MHz
1
1
13.500MHz
14.318MHz
17.73475MHz
5) Synchronization signals
The BU1424K has an "Encoder Master" mode in which
synchronization signals are output, and an "Encoder
Slave" mode in which synchronization signals are input
from an external source and used to achieve synchronization. These modes are switched at the SLABEB
pin. When the SLABEB pin is LOW, the Slave mode is
in effect, and when HIGH, the Master mode is in effect.
In the Master mode, the HSY and VSY pins serve as
output, with horizontal synchronization signals
(HSYNC) being output from the HSY pin and vertical
synchronization signals (VSYNC) from the VSY pin. At
this time, the reference timing for synchronization signal output is determined at the rising edge of the RSTB
pin. Output is obtained in accordance with the specified
mode (NTSC, PAL, or PAL60, interlace or non-interlace). Output in the non-interlace mode, however, is
output only under "Odd" field conditions (the falling
edges of HSY and VSY are the same).
In the Slave mode, the HSY and VSY pins serve as
input, and horizontal synchronization signals (HSYNC)
should be input to the HSY pin and vertical synchronization signals (VSYNC) to the VSY pin. The input
synchronization signals at this time should be input in
accordance with the specified mode. With the
BU1424K, field distinction between odd and even fields
is made automatically for each field when interlace
input is used. With the BU1424K, all synchronization
signals are treated as negative polarity signals (signals
for which the sync interval goes LOW). When using the
non-interlace mode, operation is normally carried out
under odd field conditions (the falling edges of HSY
and VSY are simultaneous).
15
Multimedia ICs
BU1424K
6) Y filter
With the BU1424K, the frequency characteristic of Y,
which is mixed with the VOUT pin output, is set so that
it can be selected using the YFILON1 and 2 pins. A
through filter is normally used on the YOUT pin output,
so that it is not limited to this method.
Table 8: Frequency characteristic of the Y channel
YFILON2B
YFILON1B
Frequency characteristic of the Y channel
H
H
TRAP filter through
(same signal as YOUT pin output is mixed with VOUT)
L
H
chart1
H
L
chart2
L
L
chart3
5
180
0
135
0
135
–5
90
–5
90
– 10
45
– 10
45
– 15
0
– 20
– 45
– 25
– 90
– 30
– 135
– 35
– 180
– 40
100
1000
10000 20000
– 45
– 25
– 90
– 30
– 135
– 35
– 180
1000
10000 20000
FREQUENCY (kHz) CONT (c), END (e), COPY (Shift + Prt Sc)
Gain-Phase Graphic
Fig.5 Chart1 (BCLK = 13.5MHz)
Fig.6 Chart2 (BCLK = 13.5MHz)
5
180
0
135
–5
90
– 10
45
– 15
0
– 20
– 45
– 25
– 90
– 30
– 135
PHASE (deg)
AMPLITUDE (dB)
0
– 20
Gain-Phase Graphic
10
– 180
– 35
1000
10000 20000
FREQUENCY (kHz) CONT (c), END (e), COPY (Shift + Prt Sc)
Gain-Phase Graphic
Fig.7 Chart3 (BCLK = 14.318MHz)
16
– 15
– 40
100
FREQUENCY (kHz) CONT (c), END (e), COPY (Shift + Prt Sc)
– 40
100
AMPLITUDE (dB)
180
PHASE (deg)
AMPLITUDE (dB)
5
PHASE (deg)
10
10
Multimedia ICs
BU1424K
(3) Output level
Figures 8 to 10 indicate the digital data values for the DAC output when the color bars from the various pins are reproduced.
WHITE
YELLOW
CYAN
GREEN
MAGEN
RED
BLUE
BLACK
BLACK LEVEL
= PEDESTAL LEVEL
SYNC TIP LEVEL
Fig.8 YOUT output
W
H
I
T
E
BLACK LEVEL
Y
E
L
L
O
W
C
Y
A
N
G
R
E
E
N
M
A
G
E
N
T
A
B
L
A
C
K
B
L
U
E
R
E
D
COLOR
BURST
Fig.9 COUT output
W
H
I
T
E
Y
E
L
L
O
W
C
Y
A
N
BLACK LEVEL
= PEDESTAL LEVEL
G
R
E
E
N
M
A
G
E
N
T
A
R
E
D
B
L
U
E
B
L
A
C
K
SYNC TIP LEVEL
Fig.10 VOUT output
17
Multimedia ICs
BU1424K
Table 9: BU1424K color bar input / output data
Input (8-bit hexadecimal for each)
RGB24bit
Output (9-bit hexadecimal for each)
YUV (4: 2: 2)
NAME&COLOR
YOUT
COUT
VOUT
RD
GD
BD
YD
UD
VD
—
—
—
—
—
—
SYNC TIP
000
—
—
—
—
—
—
—
Color Burst NTSC
—
± 039
± 039
—
—
—
—
—
—
Color Burst PAL
—
± 03D
± 03D
—
—
—
—
—
—
BLANK LEVEL
—
100
—
00
00
00
10
80
80
BLACK (Pedestal)
072
000
072
00
00
FF
28
F1
6D
BLUE
092
± 064
± 064
00
FF
00
90
36
22
GREEN
117
± 085
± 085
00
FF
FF
A9
A5
10
CYAN
138
± 08E
± 08E
FF
00
00
51
5A
F0
RED
0C6
± 08E
± 08E
FF
00
FF
6A
C9
DD
MAGENTA
0E6
± 085
± 085
FF
FF
00
D2
0E
92
YELLOW
16C
± 064
± 064
FF
FF
FF
EB
80
80
WHITE
18C
000
000
000
∗ COUT and VOUT display the chrominance amplitude. COUT is 100H ± XXXH.
VOUT is YOUT ± XXXH.
(4) Timing
Table 10 below shows the input and output pins related to timing.
Table 10: BU1424K timing-related input / output pins
Pin No.
Pin name
I/O
Function
52
RSTB
I
System reset input pin
51
VCLK
I
Clock input pin
53
CLKSW
I
Clock input mode setting pin
27
VSY
I/O
Vertical synchronization signal I / O pin
28
HSY
I/O
Horizontal synchronization signal I / O pin
16
CDGSWB
I
Video-CD / CD-G mode switching pin
22
NTB
I
NTSC / PAL mode switching pin
50
PAL60B
I
PAL / PAL60 mode switching pin
32
INT
I
Interlace / Non-interlace mode switching pin
33
SLABEB
I
Master / Slave mode switching pin
34
ADDH
I
Pin which adds 1 line in non-interlace mode
29
PIXCLK
O
1 / 2 divider output for internal clock (OSD clock)
1) Input clocks and input data timings in the various
operation modes
There are slight differences in the input data and the
clock timing, depending on which mode is being used.
18
What is shared by all modes is that, with the BU1424K,
data is read and discharged at the rising edge of the internal clock. The illustration below shows the input conditions in the various modes.
Multimedia ICs
BU1424K
1. Master mode, ∗ clock mode
Encoder master (pin 33 = H)
Internal clock = input clock (pin 53 = H)
VCLK (53pin)
BCLK
(Internal clock)
Input data
Output data
(HSY, VSY)
Tds1
Fig.11
∗ In this mode, the internal clock (BCLK) begins to operate at the same phase as the VCLK input, following the rise
of the RSTB pin (pin 52).
Table 11
Parameter
Symbol
Min.
Typ.
Max.
Tds1
10
—
—
Data setup time 1
2. Master mode, doubled clock mode
Encoder master (pin 33 = H)
Internal clock = 2 ∗ input clock (pin 53 = H)
VCLK (53pin)
BCLK
(Internal clock)
Input data
Output data
(HSY, VSY)
Tds2
Fig.12
∗ In this mode, the internal clock (BCLK) begins to operate at a halved frequency at the rise of the VCLK input, following the rise of the RSTB pin (pin 52).
Table 12
Parameter
Data setup time 2
Symbol
Min.
Typ.
Max.
Tds2
10
—
—
19
Multimedia ICs
BU1424K
3. Slave mode, single clock mode
Encoder slave (pin 33 = L)
Internal clock = input clock (pin 53 = L)
VCLK (53pin)
BCLK
(Internal clock)
Input data
output data
(HSY, VSY)
Tds3
Tsh1
Tsd1
Fig.13
∗ In this mode, the internal clock (BCLK) begins to operate at the same phase as the VCLK input, following the rise
of the RSTB pin (pin 52).
Table 13
Parameter
Symbol
Min.
Typ.
Max.
Data setup time 3
Tds3
10
—
—
Sync signal hold time
Tsh1
10
—
—
Sync signal hold time
Tsd1
10
—
—
4. Slave mode, doubled clock mode
Encoder slave (pin 33 = L)
Internal clock = 2 ∗ input clock (pin 53 = L)
VCLK (53pin)
BCLK
(Internal clock)
Input data
Input data
(HSY, VSY)
Tds4
Tsh2
Tsd2
Fig.14
20
Multimedia ICs
BU1424K
∗ In this mode, the internal clock (BCLK) begins to operate at a halved frequency at the rise of the VCLK input, following the rise of the RSTB pin (pin 52). When HSY is input, phase correction is carried out at the falling edge, as
shown in Fig. 14. (In other words, the phase of the internal clock (BCLK) is not determined until HSY is input.)
Table 14
Parameter
Symbol
Min.
Typ.
Max.
Data setup time 4
Tds4
10
—
—
Sync signal hold time 2
Tsh2
10
—
—
Sync signal setup time 2
Tsd2
10
—
—
BCLK (Internal clock)
HSY (IN / OUT)
PIXCLK
OSDSW
ROSD.GOSD
V,Y,C,OUT
VIDEO-DATA
BLACK
YELLOW
VIDEO-DATA
Fig.15 Clock timing with the OSD function
∗ The frequency of the PIXCLK pin output is one-half that of the internal clock. This phase is determined at the rising
edge of HSY, as shown in Fig. 15. (In the Encoder Master mode, phase correction is implemented using the HSY
output of the BU1424K itself.) The OSD function is effective only during the time that video output is enabled.
21
Multimedia ICs
BU1424K
2) Output timing
1. Master mode, doubled clock mode
Encoder master (pin 33 = H)
Internal clock = input clock ∗ 1 / 2 (pin 53 = L)
VCLK
BCLK (Internal clock)
HSY (OUT)
Thdf
VSY (OUT)
Thdv
PIXCLK (OUT)
Tpdr
Thdr
Tvdr
Fig.16 Output timing with a doubled clock
Table 15
Parameter
Symbol
Min.
Typ.
Max.
HSY output delay
Thdr Thdf
—
14
—
VSY output delay
Tvdr Tvdf
—
14
—
PIXCLK output delay
Tpdr Tpdf
—
14
—
2. Master mode, regular clock mode
Encoder master (pin 33 = H)
Internal clock = input clock (pin 53 = L)
VCLK
BCLK (Internal clock)
HSY (OUT)
Thdf
VSY (OUT)
Tvdf
PIXCLK (OUT)
Tpdr
Thdr
Tvdr
Fig.17 Output timing with a clock at the regular frequency
22
Multimedia ICs
BU1424K
Table 16
Parameter
Symbol
Min.
Typ.
Max.
HSY output delay
Thdr Thdf
—
10
—
VSY output delay
Tvdr Tvdf
—
10
—
PIXCLK output delay
Tpdr Tpdf
—
10
—
3) Odd / even recognition timing in Slave mode
The BU1424K distinguishes whether the conditions of
each field (each time that VSY is input) are odd or otherwise, and internal operation is carried out based on
that recognition after the data is input. As a result, HSY
and VSY are input under input conditions appropriate
to the specified mode, enabling regulated output for the
first time. Odd input conditions are indicated below.
Timing that does not match these conditions is recognized as an even field.
HSY
VSY
Tvl
Expanded view
HSY
VSY
Thvdiff
Fig.18 ODD recognition conditions
Table 17: Odd recognition conditions
Parameter
VSY input L interval
VSY Delay from HSY
Symbol
Min.
Typ.
Max.
Unit
Tvl
128
—
—
BCLK
Thvdiff
HSY falling edge
– 1clk
—
HSY Rising edge
– 2clk
BCLK
∗ BCLK = One cycle of internal clock
23
Multimedia ICs
BU1424K
4) TV signal timing diagram
VOUT
(39)
BURST
BURST
BURST
BURST
YOUT
(45)
COUT
(37)
Td1
Td2
Td3
Td4
Td5
Fig.19
Table 18
NTSC
Parameter
Symbol
Unit
SYNC rise
Td1
BCLK
Burst start
Td2
BCLK
71
Burst end
Td3
BCLK
106
Data start
Td4
BCLK
128
1-line interval
Td5
BCLK
858
24
PAL60
PAL
V-CD
CD-G
V-CD
CDG2
CDG1
V-CD
CDG2
CDG1
64
67
64
83
67
64
83
67
76
76
100
79
71
94
75
112
106
140
112
106
139
111
135
142
186
149
128
166
135
910
864
1135
908
858
1127
902
VOUT
(39pin)
Vsync (27pin)
Hsync (28pin)
VOUT
(39pin)
Vsync (27pin)
Hsync (28pin)
259
522
260
523
261
524
262
525
263
1
265
Even_Field
264
Odd_Field
2
3
266
4
267
5
268
6
269
7
270
8
271
9
272
10
273
11
274
12
18
281
19
282
20
Multimedia ICs
BU1424K
Frame timing in Video-CD mode
(NTSC / PAL60: Interlace)
Fig.20
25
26
Fig.21
VOUT (39pin)
Vsync (27pin)
Hsync (28pin)
VOUT (39pin)
Vsync (27pin)
Hsync (28pin)
310
623
311
624
312
625
2
313
3
315
Even_Field
314
Odd_Field
1
316
4
317
5
318
6
319
7
320
8
321
9
322
10
323
11
324
12
335
23
336
24
337
25
Multimedia ICs
BU1424K
Frame timing in Video-CD mode
(PAL: Interlace)
VOUT
(39pin)
Vsync (27pin)
Hsync (28pin)
VOUT
(39pin)
Vsync (27pin)
Hsync (28pin)
259
521
260
522
261
523
262
524
2
265
3
Second_Field
264
First_Field
263
1
266
4
267
5
268
6
269
7
270
8
271
9
272
10
273
11
274
12
281
18
282
19
20
Multimedia ICs
BU1424K
Frame timing in CD-G mode
(NTSC / PAL60: Non-interlace)
Fig.22
27
28
Fig.23
VOUT
(39pin)
Vsync (27pin)
Hsync (28pin)
VOUT
(39pin)
Vsync (27pin)
Hsync (28pin)
310
622
311
623
312
624
2
315
3
Second_Field
314
First_Field
313
1
316
4
317
5
318
6
319
7
320
8
321
9
322
10
323
11
324
12
335
23
336
24
337
25
Multimedia ICs
BU1424K
Frame timing in CD-G mode
(PAL: Non-interlace)
Multimedia ICs
BU1424K
(5) Adjustment of the DAC output level
The voltage level of the DAC output is determined by
the DAC internal output current and the DAC output external resistor. The output current per 1 DAC bit is determined by the external resistor of the IR pin (pin 42),
as shown below.
current of 67.71µA per 1LSB is output. Because the
white level of Y is a digital value of 396 (decimal value),
the following results:
V (Y white) = 0.0677 × 396 = 26.81[mA]
At this point, if the DAC output external resistance is
37.5Ω, an amplitude of 1.005[VP-P] is obtained.
I (1LSB) = VVREF / RIR ∗ 1 / 16 [A]······ (equation 6-1)
(6) YUV input mode
With the BU1424K, setting the IM0 pin (pin 23) to HIGH
enables a 16-bit YUV input format to be supported. At
that time, the timing of U and V can be reversed when
data is input, using the H / L state of the Test2 pin.
The input conditions for this mode are shown below.
VREF······Voltage generated by the regulator circuit in
the BU1424K [V]
RIR·········External resistor for the IR pin 1200 [Ω]
Consequently, when VREF = 1.3V and RIR = 1200Ω, a
0
1
2
2n 2n + 1
Internal clock (BCLK)
HSY
Y-Data
U.V-Data
Y1
Y2
Y3
Y4
Y5
U1
V1
U3
V3
U5
Y1
Y2
Y3
Y4
Y5
U1
V1
U3
V3
U5
Fig.24 YUV input timing when TEST [2] = L
0
1
2
2n 2n + 1
Internal clock (BCLK)
HSY
Y-Data
U.V-Data
Fig.25 YUV input timing when TEST [2] = H
Reversal of the U and V timing using the H / L state of TEST[2] can be controlled regardless of whether CLKSW is
HIGH or LOW (the input clock is a doubled clock or not).
29
Multimedia ICs
BU1424K
∗ When using the RGB input mode, TEST[2] should be fixed at LOW.
∗ In the Master mode, HSYNC is output at the timing shown on the previous page. For that reason, the timing of U
and V should be determined by counting from that falling edge. In the Slave mode, the HSY, U, and V data should
be input at the timing shown on the previous page.
Table 19
TEST2
(26pin)
CLKSW
(53pin)
0
0
0
1
In a doubled clock mode, the timing of U and V is as shown in Fig. 24
In a regular clock mode, the timing of U and V is as shown in Fig. 24
1
1
0
1
In a doubled clock mode, the timing of U and V is as shown in Fig. 25
In a regular clock mode, the timing of U and V is as shown in Fig. 25
•External dimensions (Units: mm)
12.0 ± 0.3
10.0 ± 0.2
16
0.8
0.35 ± 0.1
0.15 ± 0.1
17
64
0.5
16
30
0.125 ± 0.1
0.2 ± 0.1
0.1
0.15
QFP-A64
0.5
12.0 ± 0.3
10.0 ± 0.2
33
32
49
1
1.4 ± 0.1
1
0.5
17
64
0.10
2.7 ± 0.1
48
32
49
0.05
16.4 ± 0.3
14.0 ± 0.2
16.4 ± 0.3
14.0 ± 0.2
48
33
VQFP64
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