Philips SAA7187WP-00, SAA7187WP-01 Datasheet

DATA SH EET
Preliminary specification File under Integrated Circuits, IC22
1995 Sep 21
INTEGRATED CIRCUITS
SAA7187
Digital video encoder (DENC2-SQ)
1995 Sep 21 2
Digital video encoder (DENC2-SQ) SAA7187
FEATURES
CMOS 5 V device
Digital PAL/NTSC encoder
System pixel frequency selectable for 12.27 MHz (60 Hz
fields) or 14.75 MHz (50 Hz fields)
24-bit wide YUV input port or
16-bit wide YUV input port or
Input data format Cb, Y, Cr, etc. (CCIR 656)
I2C-bus control port
MPU parallel control port
Encoder can be master or slave
Programmable horizontal and vertical input
synchronization phase
Programmable horizontal sync output phase
OSD overlay with Look-Up Tables (LUTs) 8 × 3 bytes
Line 21 Closed Caption encoder
Cross-colour reduction
DACs operating at twice oversampling with 10-bit
resolution
Controlled rise/fall times of output syncs and blanking
Down-mode of DACs
CVBS and S-Video output simultaneously
PLCC68 package.
GENERAL DESCRIPTION
The SAA7187 encodes digital YUV video data to an NTSC, PAL CVBS or S-Video signal.
The circuit accepts differently formatted YUV data with 640 or 768 active pixels per line. It includes a sync/clock generator and on-chip Digital-to-Analog Converters (DACs).
The circuit is compatible to the DIG-TV2 chip family (Square Pixel).
QUICK REFERENCE DATA
ORDERING INFORMATION
SYMBOL PARAMETER MIN. TYP. MAX. UNIT
V
DDA
analog supply voltage 4.75 5.0 5.25 V
V
DDD
digital supply voltage 4.5 5.0 5.5 V
I
DDA
analog supply current 50 55 mA
I
DDD
digital supply current 175 210 mA
V
i
input signal voltage levels TTL compatible
V
o(p-p)
analog output signal voltages Y, C and CVBS without load (peak-to-peak value)
2 V
R
L
load resistance 80 −−Ω ILE LF integral linearity error −−±2 LSB DLE LF differential linearity error −−±1 LSB T
amb
operating ambient temperature 0 +70 °C
TYPE NUMBER
PACKAGE
NAME DESCRIPTION VERSION
SAA7187 PLCC68 plastic leaded chip carrier; 68 leads SOT188-2
1995 Sep 21 3
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
BLOCK DIAGRAM
handbook, full pagewidth
CONTROL
INTERFACE
DATA
MANAGER
ENCODER
internal control bus
clock timing signals
OUTPUT
INTERFACE
SYNC
CLK
A
V
DDD1
to V
DDD4
48,50,
54,56
D
5547
53 51
49
52 46
43
RTCI
V
refH
V
DDA4
V
DDA1
88
SAA7187
8
8
8
8 8
8
6168
SEL_MPU
CS/SA
1,8,19 28,35,
62
VP3
(0 to 7)
VP2
(0 to 7)
VP1
(7 to 0)
V
SSD1
V
SSD6
63 to 66
2 to 5
59 60 58 57 41 40 38 39 36 6 7
31
KEY
OSD0
to OSD2
32 to 34
20 to 27
9 to 16
18
29
RCM1 RCM2
30
17,37,42,67
to
RW/SCL
A0/SDA
DTACK
RESET
XTALI
XTALO
LLC
CREF
CDIR
RCV1
RCV2 n.c.
CVBS Y
to
I
I
CHROMA
V
SSA
V
refL
MBG253
Fig.1 Block diagram.
1995 Sep 21 4
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
PINNING
SYMBOL PIN DESCRIPTION
V
SSD1
1 digital ground 1
VP3(4) 2
Upper 4 bits of the Video Port VP3. If pin 68 (SEL_MPU) is HIGH, this is the data bus of the parallel MPU interface. If it is LOW, there can be multiplexed UV lines (422) or the U signal (444) of the Video input.
VP3(5) 3 VP3(6) 4 VP3(7) 5 RCV1 6 Raster Control 1 for Video port. Depending on the synchronization mode, this pin
receives/provides a VS/FS/FSEQ signal.
RCV2 7 Raster Control 2 for Video port. Depending on the synchronization mode, this pin
receives/provides an HS/HREF/CBL signal.
V
SSD2
8 digital ground 2
VP2(0) 9
Video Port VP2. In 444 input mode, this is input for the V-signal.
VP2(1) 10 VP2(2) 11 VP2(3) 12 VP2(4) 13 VP2(5) 14 VP2(6) 15 VP2(7) 16 V
DDD1
17 digital supply voltage 1 n.c. 18 reserved, do not connect V
SSD3
19 digital ground 3 VP1(7) 20
Video Port VP1. This is an input for CCIR 656 compatible, multiplexed video data, or during other input modes, this is the Y-signal.
VP1(6) 21 VP1(5) 22 VP1(4) 23 VP1(3) 24 VP1(2) 25 VP1(1) 26 VP1(0) 27 V
SSD4
28 digital ground 4 RCM1 29 Raster Control Master 1. This pin provides a VS/FS/FSEQ signal. RCM2 30 Raster Control Master 2. This pin provides a programmable HS pulse. KEY 31 Key signal for OSD. It is active HIGH. OSD0 32
On-Screen Display data. This is the index for the internal OSD look-up table.OSD1 33 OSD2 34 V
SSD5
35 digital ground 5
CDIR 36 Clock direction. If the CDIR input is HIGH, the circuit receives a clock signal, otherwise LLC
and CREF are generated by the internal crystal oscillator. V
DDD2
37 digital supply voltage 2
1995 Sep 21 5
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
LLC 38 Line-Locked Clock. This is the 24.54 MHz or 29.5 MHz master clock for the encoder. The
direction is set by the CDIR pin. CREF 39 Clock Reference signal. This is the clock qualifier for DIG-TV2 compatible signals. XTALO 40 Crystal oscillator output (to crystal). XT ALI 41 Crystal oscillator input (from crystal). If the oscillator is not used, this pin should be connected
to ground. V
DDD3
42 digital supply voltage 3
RTCI 43 Real Time Control Input. If the clock is provided by an SAA7191B, RTCI should be connected
to the RTCO pin of the decoder to improve the signal quality. AP 44 Test pin. Connected to digital ground for normal operation. SP 45 Test pin. Connected to digital ground for normal operation. V
refL
46 Lower reference voltage input for the DACs.
V
refH
47 Upper reference voltage input for the DACs.
V
DDA1
48 Analog supply voltage 1 for the DACs and output amplifiers. CHROMA 49 Analog output of the chrominance signal. V
DDA2
50 Analog supply voltage 2 for the DACs and output amplifiers. Y 51 Analog output of the luminance signal. V
SSA
52 Analog ground for the DACs and output amplifiers. CVBS 53 Analog output of the CVBS signal. V
DDA3
54 Analog supply voltage 3 for the DACs and output amplifiers. I
I
55 Current input for the output amplifiers, connect via a 15 k resistor to V
DDA
.
V
DDA4
56 Analog supply voltage 4 for the DACs and output amplifiers. RESET 57 Reset input, active LOW. After reset is applied, all outputs are in 3-state input mode.
The I2C-bus receiver waits for the START condition.
DTACK 58 Data acknowledge output of the parallel MPU interface, active LOW, otherwise high
impedance.
R
W/SCL 59 If pin 68 (SEL_MPU) is HIGH, this is the read/write signal of the parallel MPU interface,
otherwise it is the I2C-bus serial clock input.
A0/SDA 60 If pin 68 (SEL_MPU) is HIGH, this is the address signal of the parallel MPU interface,
otherwise it is the I
2
C-bus serial data input/output.
CS/SA 61 If pin 68 (SEL_MPU) is HIGH, this is the chip select signal of the parallel MPU interface,
otherwise it is the I2C-bus slave address select pin. LOW: slave address = 88H, HIGH = 8CH.
V
SSD6
62 digital ground 6 VP3(0) 63
Lower 4 bits of the Video Port VP3. If pin 68 (SEL_MPU) is HIGH, this is the data bus of the parallel MPU interface. If it is LOW, there can be multiplexed UV lines (422) of the U-signal (444) of the Video input.
VP3(1) 64 VP3(2) 65 VP3(3) 66 V
DDD4
67 digital supply voltage 4 SEL_MPU 68 Select MPU interface input. If it is HIGH, the parallel MPU interface is active, otherwise the
I
2
C-bus interface will be used.
SYMBOL PIN DESCRIPTION
1995 Sep 21 6
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
Fig.2 Pin configuration.
handbook, full pagewidth
MBG252
SAA7187
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27
61 62 63 64 65 66 67 68
1 2 3 4 5 6 7 8 9
VP2(1)
VP2(2)
VP2(3)
VP2(4)
VP2(5)
VP2(6)
VP2(7)
VP1(7)
VP1(6)
VP1(5)
VP1(4)
VP1(3)
VP1(2)
VP1(1)
n.c.
V
DDD1
V
SSD3
AP
SP
CHROMA
Y
CVBS
RESET
V
refL
V
refH
V
DDA1
V
DDA2
V
DDA3
V
DDA4
I
I
V
SSA
VP1(0)
KEY
OSD0
OSD1
OSD2
CDIR
CREF
XTALO
XTALI
RTCI
LLC
RCM1
RCM2
V
SSD4
V
SSD5
V
DDD2
V
DDD3
CS/SA
VP3(0) VP3(1) VP3(2)
VP3(3)
VP3(4)
VP3(5) VP3(6) VP3(7)
VP2(0)
RCV1
RCV2
SEL_MPU
V
SSD6
V
DDD4
V
SSD1
V
SSD2
DTACK
RW/SCL
A0/SDA
1995 Sep 21 7
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
FUNCTIONAL DESCRIPTION
The digital video encoder (DENC2-SQ) encodes digital luminance and chrominance into analog CVBS and simultaneously S-Video (Y/C) signals. NTSC-M and PAL B/G standards also sub-standards are supported.
The basic encoder function consists of subcarrier generation and colour modulation also insertion of synchronization signals. Luminance and chrominance signals are filtered in accordance with the standard requirements RS-170-A and CCIR 624.
For ease of analog post filtering the signals are twice oversampled with respect to pixel clock before digital-to-analog conversion.
For total filter transfer characteristics see Figs 3 to 6 for 60 Hz field rate, and Figs 7 to 10 for 50 Hz field rate. The DACs are realized with full 10-bit resolution. The encoder provides three 8-bit wide data ports, that serve different applications.
The VP1 port accepts 8 lines multiplexed Cb-Y-Cr data (CCIR 656 mode), or Y data only (444 mode).
The VP2 port accepts Cr data in 444 input mode. The VP3 port accepts Cb data (444 input mode) or
multiplexed Cb/Cr data (422 input mode). If not used for video input data, it can alternatively also handle the data of an 8-bit wide microprocessor interface.
Minimum suppression of output chrominance alias components approximately 1 MHz due to high frequency 444 input is better than 12 dB.
The 8-bit multiplexed Cb-Y-Cr formats are CCIR 656 (D1 format) compatible, but the SAV, EAV, etc. codes are not decoded.
A crystal-stable master clock (LLC) of 24.54 or 29.5 MHz, which is twice the line-locked pixel clock, needs to be supplied externally. Optionally, a crystal oscillator input/output pair of pins and an on-chip clock driver is provided. Additionally, a DMSD2 compatible clock interface, using CREF (input or output) and RTC (see
“data sheet SAA7191B”
) is available.
The DENC2-SQ synthesizes all necessary internal signals, colour subcarrier frequency, and synchronization signals, from that clock. DENC2-SQ can be timing master or slave.
The IC also contains Closed Caption and Extended Data Services Encoding (Line 21); it also supports OSD via KEY and three-bit overlay techniques by a 24 × 8 LUT.
The IC can be programmed via I
2
C-bus or 8-bit MPU interface, but only one interface configuration can be active at a time; if 422 or 444 input format is being used, only the I2C-bus interface can be selected.
A number of possibilities are provided for setting of different video parameters such as:
Black and blanking level control Colour subcarrier frequency Variable burst amplitude etc.
During reset (RESET = LOW) and after reset is released, all digital I/O stages are set to input mode. A reset forces the control interfaces to abort any running bus transfer and to set register 3AH to contents 00H, register 61H to contents 15H, and register 6CH to contents 00H. All other control registers are not influenced by a reset.
Data manager
In the data manager, the demultiplexing scheme is chosen in accordance with the input format.
Depending on hardware conditions (signals on pins KEY, OSD2 to OSD0), and software programming either data from the VP ports or from the OSD port are selected to be encoded to CVBS and Y/C signals.
Optionally, the OSD colour look-up tables located in this block, can be read out in a pre-defined sequence (8 steps per active video line), achieving e.g. a colour bar test pattern generator without need for an external data source. The colour bar function is only under software control.
Encoder
V
IDEO PATH
The encoder generates out of Y, U and V baseband signals luminance and colour subcarrier output signals, suitable for use as CVBS or separate Y/C signals.
Luminance is modified in gain and in offset (latter programmable in a certain range to enable different black level set-ups). After having been inserted a fixed synchronization level, in accordance with standard composite synchronization schemes, a variable blanking level, programmable also in a certain range, is inserted.
Transients of both synchronization pulses and start/stop of blanking are reduced compared to overall luminance bandwidth.
1995 Sep 21 8
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
In order to enable easy analog post filtering, luminance is interpolated from square pixel data rate to twice that rate (24.54 or 29.5 MHz respectively), providing luminance in 10-bit resolution. For transfer characteristic of the luminance interpolation filter see Figs 5 and 6 for 60 Hz field rate and Figs 9 and 10 for 50 Hz field rate.
Chrominance is modified in gain (programmable separately for U and V), standard dependent burst is inserted, before baseband colour signals are interpolated correctly to 24.54 or 29.5 MHz data rate. One of the interpolation stages can be bypassed, thus providing a higher colour bandwidth, which can be made use of for Y/C output. For transfer characteristics of the chrominance interpolation filter see Figs 3 and 4 for 60 Hz field rate and Figs 7 and 8 for 50 Hz field rate.
The amplitude of inserted burst is programmable in a certain range, suitable for standard signals and for special effects. Behind the succeeding quadrature modulator, colour in 10-bit resolution is provided on subcarrier.
The numeric ratio between Y and C outputs is in accordance with set standards.
C
LOSED CAPTION ENCODER
Using this circuit, data in accordance with the specification of Closed Caption or Extended Data Service, delivered by the control interface, can be encoded (Line 21). Two dedicated pairs of bytes (two bytes per field), each pair preceded by run-in clocks and framing code, are possible.
The actual line number where data is to be encoded in, can be modified in a certain range.
Data clock frequency is in accordance with definition for NTSC-M standard 32 times horizontal line frequency.
Data LOW at the output of the DACs corresponds to 0 IRE, data HIGH at the output of the DACs corresponds to approximately 50 IRE.
It is also possible to encode Closed Caption Data for 50 Hz field frequencies at 32 times horizontal line frequency.
Output interface
In the output interface encoded Y and C signals are converted from digital-to-analog in 10-bit resolution both Y and C signals are combined to a 10-bit CVBS signal, also; in front of the summation point, the luminance signal can optionally be fed through a further filter stage, suppressing components in the range of subcarrier frequency. Thus, a type of cross colour reduction is provided, which is useful in a standard TV set with CVBS input.
Slopes of synchronization pulses are not affected with any cross colour reduction active.
Three different filter characteristics or bypass are available, see Fig.5 for 60 Hz field rate and Fig.9 for 50 Hz field rate.
The CVBS output occurs with the same processing delay as the Y and C outputs. Absolute amplitudes at the input of the DAC for CVBS is reduced by15⁄16 with respect to Y and C DACs to make maximum use of conversion ranges.
Outputs of all DACs can be set together via software control to minimum output voltage for either purpose.
Synchronization
The synchronization of the DENC2-SQ is able to operate in two modes; slave mode and master mode.
In the slave mode, the circuit accepts synchronization pulses at the bidirectional RCV1 port. The timing and trigger behaviour related to the video signal on VP ports can be influenced by programming the polarity and on-chip delay of RCV1. Active slope of RCV1 defines the vertical phase and optionally the odd/even and colour frame phase to be initialized, it can be also used to set the horizontal phase.
If the horizontal phase is not be influenced by RCV1, a horizontal pulse needs to be supplied at the RCV2 pin. Timing and trigger behaviour can also be influenced for RCV2.
1995 Sep 21 9
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
If there are missing pulses at RCV1 and/or RCV2, the time base of DENC2-SQ runs free, thus an arbitrary number of synchronization slopes may miss, but no additional pulses (such with wrong phase) must occur.
If the vertical and horizontal phase is derived from RCV1, RCV2 can be used for horizontal or composite blanking input or output.
In the master mode, the time base of the circuit continuously runs free. On the RCV1 port, the IC can output:
A Vertical Sync signal (VS) with 3 or 2.5 lines duration, or
An ODD/EVEN signal which is LOW in odd fields, or
A field sequence signal (FSEQ) which is HIGH in the first
of 4 respectively 8 fields.
On the RCV2 port, the IC can provide a horizontal pulse with programmable start and stop phase; this pulse can be inhibited in the vertical blanking period to build up e.g. a composite blanking signal.
The phase of the pulses output on RCV1 or RCV2 are referenced to the VP ports, polarity of both signals is selectable.
On the RCM1 port the same signals as on RCV1 (as output) are available; on RCM2 the IC provides a horizontal pulse with programmable start and stop phase.
The length of a field also start and end of its active part can be programmed. The active part of a field always starts at the beginning of a line.
Control interface
DENC2-SQ contains two control interfaces: an I
2
C-bus slave transceiver and 8-bit parallel microprocessor interface. The interfaces cannot be used simultaneously.
The I2C-bus interface is a standard slave transceiver, supporting 7-bit slave addresses and 100 kbits/s guaranteed transfer rate. It uses 8-bit subaddressing with an auto-increment function. All registers are write only, except one readable status byte.
Two I
2
C-bus slave addresses can be selected
(pin SEL_MPU must be LOW):
88H: LOW at pin 61 8CH: HIGH at pin 61.
The parallel interface is defined by:
D7 to D0 data bus CS active-LOW chip select signal RW read/not write signal, LOW for a write cycle DTACK 680xx style data acknowledge (handshake),
active-LOW A0 register select, LOW selects address, HIGH selects
data.
The parallel interface uses two registers, one auto-incremental containing the current address of a control register (equals subaddress with I2C-bus control), one containing actual data. The currently addressed register is mapped to the corresponding control register.
The status byte can be read optionally via a read access to the address register, no other read access is provided.
Input levels and formats
DENC2-SQ expects digital YUV data with levels (digital codes) in accordance with CCIR 601.
Deviating amplitudes of the colour difference signals can be compensated by independent gain control setting, while gain for luminance is set to predefined values, distinguishable for 7.5 IRE set-up or without set-up.
Reference levels are measured with a colour bar, 100% white, 100% amplitude and 100% saturation.
When the IC is operating with input data in accordance with CCIR 656, programming can be carried out alternatively via the parallel interface using VP3 port for data transfer.
For other input modes, the I
2
C-bus interface has to be
used for programming.
1995 Sep 21 10
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
Table 1 CCIR signal component levels
Table 2 8-bit multiplexed format (similar to CCIR 656)
Table 3 16-bit multiplexed format (DTV2 format)
Table 4 24-bit direct 444 format
SIGNAL IRE DIGITAL LEVEL CODE
Y
016
straight binary50 126
100 235
Cb
bottom peak 16
straight binarycolourless 128
top peak 240
Cr
bottom peak 16
straight binarycolourless 128
top peak 240
TIME
FORMAT
01234567
Sample Cb
0
Y
0
Cr
0
Y
1
Cb
2
Y
2
Cr
2
Y
3
Luminance pixel number 0 1 2 3 Colour pixel number 0 2
TIME
FORMAT
01234567
Sample Y line Y
0
Y
1
Y
2
Y
3
Sample UV line Cb
0
Cr
0
Cb
2
Cr
2
Luminance pixel number 0 1 2 3 Colour pixel number 0 2
TIME
FORMAT
01234567
Sample Y line Y
0
Y
1
Y
2
Y
3
Sample U line Cb
0
Cb
1
Cb
2
Cb
3
Sample V line Cr
0
Cr
1
Cr
2
Cr
3
Luminance pixel number 0 1 2 3 Colour pixel number 0 1 2 3
1995 Sep 21 11
Philips Semiconductors Preliminary specification
Digital video encoder (DENC2-SQ) SAA7187
Bit allocation map
Table 5 Slave receiver (slave address 88H or 8CH)
REGISTER FUNCTION
SUB
ADDRESS
DATA BYTE
D7 D6 D5 D4 D3 D2 D1 D0
Null 00 00000000
01 to 38
Null 39 00000000
Input port control 3A CBENB 0 0 0 VY2C VUV2C FMT1 FMT0
OSD LUT Y0 42 OSDY07 OSDY06 OSDY05 OSDY04 OSDY03 OSDY02 OSDY01 OSDY00
OSD LUT U0 43 OSDU07 OSDU06 OSDU05 OSDU04 OSDU03 OSDU02 OSDU01 OSDU00
OSD LUT V0 44 OSDV07 OSDV06 OSDV05 OSDV04 OSDV03 OSDV02 OSDV01 OSDV00
45 to 56
OSD LUT Y7 57 OSDY77 OSDY76 OSDY75 OSDY74 OSDY73 OSDY72 OSDY71 OSDY70
OSD LUT U7 58 OSDU77 OSDU76 OSDU75 OSDU74 OSDU73 OSDU72 OSDU71 OSDU70
OSD LUT V7 59 OSDV77 OSDV76 OSDV75 OSDV74 OSDV73 OSDV72 OSDV71 OSDV70
Chrominance phase 5A CHPS7 CHPS6 CHPS5 CHPS4 CHPS3 CHPS2 CHPS1 CHPS0
Gain U 5B GAINU7 GAINU6 GAINU5 GAINU4 GAINU3 GAINU2 GAINU1 GAINU0
Gain V 5C GAINV7 GAINV6 GAINV5 GAINV4 GAINV3 GAINV2 GAINV1 GAINV0
Gain U MSB, black level 5D GAINU8 0 BLCKL5 BLCKL4 BLCKL3 BLCKL2 BLCKL1 BLCKL0
Gain V MSB, blanking level 5E GAINV8 0 BLNNL5 BLNNL4 BLNNL3 BLNNL2 BLNNL1 BLNNL0
Null 5F 00000000
Cross-colour select 60 CCRS1 CCRS0 000000
Standard control 61 0 DOWN INPI1 YGS RTCE SCBW PAL FISE
Burst amplitude 62 SQP BSTA6 BSTA5 BSTA4 BSTA3 BSTA2 BSTA1 BSTA0
Subcarrier 0 63 FSC07 FSC06 FSC05 FSC04 FSC03 FSC02 FSC01 FSC00
Subcarrier 1 64 FSC15 FSC14 FSC13 FSC12 FSC11 FSC10 FSC09 FSC08
Subcarrier 2 65 FSC23 FSC22 FSC21 FSC20 FSC19 FSC18 FSC17 FSC16
Subcarrier 3 66 FSC31 FSC30 FSC29 FSC28 FSC27 FSC26 FSC25 FSC24
Line 21 odd 0 67 L21O07 L21O06 L21O05 L21O04 L21O03 L21O02 L21O01 L21O00
Line 21 odd 1 68 L21O17 L21O16 L21O15 L21O14 L21O13 L21O12 L21O11 L21O10
Line 21 even 0 69 L21E07 L21E06 L21E05 L21E04 L21E03 L21E02 L21E01 L21E00
Line 21 even 1 6A L21E17 L21E16 L21E15 L21E14 L21E13 L21E12 L21E11 L21E10
CC line 6B 0 0 0 SCCLN4 SCCLN3 SCCLN2 SCCLN1 SCCLN0
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