Gennum GS1675 Differential inputs and output Datasheet

GS1675 SD/HD SDI Reclocker
The GS1675 is a multi-rate serial digital reclocker designed to automatically recover the embedded clock from a digital video signal and
retime the incoming video data. It will recover the embedded clock signal and retime the data from a SMPTE 292M or SMPTE 259M-C
compliant digital video signal.
The GS1675 can operate in either Auto or Manual rate selection mode. In Auto mode, the device will automatically detect and lock onto
incoming SMPTE SDI data signals at SD and HD data rates. For single-rate data systems, the GS1675 can be configured to operate in
Manual mode. In both modes, the device requires only one external crystal to set the VCO frequency when not locked, and provides
adjustment-free operation. In systems which require passing non-SMPTE data rates, the GS1675 can be configured to either
automatically or manually enter a bypass mode in order to pass the signal without reclocking.
The GS1675 accepts industry-standard differential input levels including LVPECL and CML. The differential data and clock outputs
feature selectable output swing via the host interface, ensuring compatibility with most industry-standard, terminated differential
receivers. The GS1675 features dual differential outputs. The second output can be configured to emit either the recovered clock signal
or the re-timed video data.
•
Key Features
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SMPTE 292M and SMPTE 259M-C compliant
Supports DVB-ASI at 270Mb/s
Single-supply operation at 3.3V or 2.5V
180mW typical power consumption (213mW with RCO
enabled) at 2.5V
2:1 input multiplexer patented technology
Choice of dual reclocked data outputs or one reclocked data
output and one clock output
Uses standard 27MHz crystal
Differential inputs and outputs
Š supports DC-coupling to industry-standard differential
logic
Š on-chip 100Ω differential data input/output termination
Š selectable 400mVppd or 800mVppd output swing on
each output
4-wire SPI host interface for device configuration and
monitoring
Standard logic control and status signal levels
Auto and Manual modes for rate selection
Standards indication in Auto mode
Lock Detect Output
Mute, Bypass and Autobypass functions
SD/HD indication output to control GS1678 or GS1679 cable
drivers
Operating temperature range: -40°C to +85°C
32 pin 5mm x 5mm QFN package
Pb-free and RoHS compliant
Forward pin-compatible with the Gennum's 3G GS2965
reclocker
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Typical Application Circuit
3
VCC2
JP5
2
VCO_SEL
1
R23
R24
422R
267R
VCC2
VDD_DIG
(Pin14)
VCC_VCO
(Pin9)
C31 C30
C33
10u
C32
1u 10n
C34
VCC_DDO1
(Pin19)
VCC_DDO0
(Pin23)
C20 C23 C27
10n
C13 C15 C16
10n DNP DNP
10n DNP DNP
VCC_CP
(Pin32)
C7
10n
220n
GND
VEE_DDO1
(Pin20)
VEE_DDO0
(Pin24)
Data Input 1
7
HIFb
4
CSb
SCK
SDO
SDI
27
28
29
30
8
1
2
C3
47n
C4
220n
DDO0
DDO0
DDI1
DDO1/RCO
DDI1
DDO1/RCO
GS1675
CS
SCK
SDO
SDI
XTAL-
22
21
Data Output 0
18
17
Data Output 1
ABM7-27.000MHZ-D2Y-T
26
Y1
R6
C1
25
XTAL+
NC
LF+
CP_CAP
SD/HD
LOS
LOCKED
18p
GND
1M
16
13
12
C2
SD/HD
LOS
LOCKED
18p
GND
10
15
20
24
31
GND
DDI0
DDI0
HIF
VEE_CP
(Pin31)
GND
TAB
6
VEE_VCO
VSS_DIG
VEE_DDO1
VEE_DDO0
VEE_CP
3
5
Data Input 0
SPI
VSS_DIG
(Pin15)
VDD_1P8
VCC_VCO
VDD_DIG
VCC_DDO1
VCC_DDO0
VCC_CP
U2
11
9
14
19
23
32
VEE_VCO
(Pin10)
GND
GND
GS1675 SD/HD SDI Reclocker
Data Sheet
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June 2011
www.gennum.com
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Contents
Key Features........................................................................................................................................................1
Typical Application Circuit.............................................................................................................................1
1. Pin Out...............................................................................................................................................................4
1.1 Pin Assignment ..................................................................................................................................4
1.2 Pin Descriptions ................................................................................................................................5
1.3 Default Start-up Settings ................................................................................................................7
2. Electrical Characteristics ............................................................................................................................8
2.1 Absolute Maximum Ratings ..........................................................................................................8
2.2 DC Electrical Characteristics ........................................................................................................8
2.3 AC Electrical Characteristics ........................................................................................................9
3. Functional Description ............................................................................................................................. 11
3.1 Serial Data Input ............................................................................................................................ 11
3.2 Modes of Operation ...................................................................................................................... 11
3.3 2:1 Input Mux .................................................................................................................................. 11
3.4 Crystal Buffer .................................................................................................................................. 12
3.5 LOS (Loss Of Signal) Detection .................................................................................................. 12
3.6 Serial Digital Reclocker ............................................................................................................... 13
3.7 Lock Detection ................................................................................................................................ 13
3.7.1 Lock Detect and Asynchronous Lock ......................................................................... 14
3.8 Serial Data Output ......................................................................................................................... 14
3.8.1 Output Signal Interface Levels...................................................................................... 14
3.8.2 Adjustable Output Swing................................................................................................ 14
3.9 Automatic and Manual Data Rate Selection ......................................................................... 14
3.10 SD/HD Indication ........................................................................................................................ 15
3.11 Bypass Mode ................................................................................................................................. 15
3.12 DVB-ASI ......................................................................................................................................... 16
3.13 Output Mute and Data/Clock Output Selection ............................................................... 16
3.14 Host Interface ............................................................................................................................... 17
3.14.1 Introduction ...................................................................................................................... 17
3.14.2 Legacy Mode & Startup ................................................................................................. 17
3.14.3 Host Interface Mode & Startup ................................................................................... 17
3.14.4 Clock & Data Timing....................................................................................................... 18
3.14.5 Single Device Operation............................................................................................... 18
3.14.6 Write Operation - Single Device ................................................................................ 19
3.14.7 Read Operation - Single Device ................................................................................. 20
3.14.8 Daisy Chain Operation.................................................................................................. 22
3.14.9 Read & Write Operation - Daisy Chained Devices .............................................. 23
3.14.10 Writing to all Devices .................................................................................................. 23
3.14.11 Writing to a Single Device in the Chain ................................................................ 24
3.14.12 Reading from all Devices ........................................................................................... 24
3.14.13 Reading from a Single Device in the Chain.......................................................... 25
3.14.14 Host Register Map......................................................................................................... 26
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3.15 Device Power Up ......................................................................................................................... 29
3.16 Standby ........................................................................................................................................... 29
4. Typical Application Circuit ..................................................................................................................... 30
5. Input/Output Circuits ............................................................................................................................... 31
6. Package and Ordering Information...................................................................................................... 34
6.1 Package Dimensions ..................................................................................................................... 34
6.2 Recommended PCB Footprint ................................................................................................... 34
6.3 Packaging Data ............................................................................................................................... 35
6.4 Marking Diagram ........................................................................................................................... 35
6.5 Solder Reflow Profile .................................................................................................................... 36
6.6 Ordering Information ................................................................................................................... 36
Revision History .............................................................................................................................................. 37
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Data Sheet
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June 2011
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1. Pin Out
VCC_CP
VEE_CP
SDI
SDO
SCK
CS
XTAL-
XTAL+
1.1 Pin Assignment
32
31
30
29
28
27
26
25
LF+
1
24
VEE_DDO0
CP_CAP
2
23
VCC_DDO0
DDI0
3
22
DDO0
HIF
4
21
DDO0
DDI0
5
20
VEE_DDO1
DDI1
6
19
VCC_DDO1
DDI1
7
18
DDO1/RCO
RSVD
8
17
DDO1/RCO
13
14
15
16
VDD_DIG
VSS_DIG
SD/HD
12
LOCKED
11
VDD_1P8
10
VEE_VCO
Ground Pad
(bottom of package)
VCC_VCO
9
LOS
GS1675
32-pin QFN
(top view)
Figure 1-1: GS1675 Pin Out
GS1675 SD/HD SDI Reclocker
Data Sheet
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June 2011
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1.2 Pin Descriptions
Table 1-1: GS1675 Pin Descriptions
Pin Number
Name
Type
Description
1
LF+
Passive
Loop Filter Capacitor connection (CLF = 47nF). Connect as shown in the
Typical Application Circuit on page 30.
2
CP_CAP
Power
External capacitor for internal LDO regulator supplying the charge pump
circuit.
3, 5
DDI0, DDI0
Input
Serial Digital Differential Input 0.
4
HIF
Logic Input
6, 7
DDI1, DDI1
Input
8
RSVD
Reserved
9
VCC_VCO
Power
Most positive power supply connection for the internal
VCO section. Connect to a 3.3V supply with a 422Ω resistor, or a 2.5V
supply with a 267Ω resistor.
10
VEE_VCO
Power
Most negative power supply connection for the internal
VCO section. Connect to GND.
11
VDD_1P8
Power
External capacitor for internal 1.8V digital supply.
12
LOCKED
Output
Lock Detect status signal. HIGH when the PLL is locked.
13
LOS
Output
Loss Of Signal status. HIGH when the input signal is invalid.
14
VDD_DIG
Power
Most positive power supply connection for the digital core.
Connect to 3.3V or 2.5V.
15
VSS_DIG
Power
Most negative power supply for the digital core.
Connect to GND.
16
SD/HD
Output
This signal will be LOW for all rates other than 270Mb/s.
This signal is HIGH for 270Mb/s.
17, 18
DDO1/RCO,
DDO1/RCO
Output
Differential serial clock or data outputs.
19
VCC_DDO1
Power
Most positive power supply connection for the DDO1/DDO1 output driver.
Connect to 3.3V or 2.5V.
20
VEE_DDO1
Power
Most negative power supply connection for the DDO1/DDO1 output
driver. Connect to GND.
21, 22
DDO0, DDO0
Output
Differential Serial Digital Outputs.
23
VCC_DDO0
Power
Most positive power supply connection for the DDO0/DDO0 output driver.
Connect to 3.3V or 2.5V.
24
VEE_DDO0
Power
Most negative power supply connection for the DDO0/DDO0 output
driver.
Host interface selection pin. Active-low input. See Section 3.14.1.
Serial Digital Differential Input 1.
Reserved pin. Do not connect to this pin.
Connect to GND.
25
XTAL+
GS1675 SD/HD SDI Reclocker
Data Sheet
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June 2011
Output
Reference crystal output.
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Table 1-1: GS1675 Pin Descriptions (Continued)
Pin Number
Name
Type
26
XTAL-
Input
27
CS
Input/Logic
Input
Description
Reference crystal input.
In host mode (HIF set LOW):
Chip select input for SPI serial host interface. Active-low input.
In non-host mode (HIF set HIGH):
Set LOW. Gennum recommends using a weak pull-down resistor (~50kΩ).
28
SCK
Input/Logic
Input
In host mode (HIF set LOW):
Burst-mode clock input for SPI serial host interface.
In non-host mode (HIF set HIGH):
Set LOW. Gennum recommends using a weak pull-down resistor (~50kΩ).
29
SDO
Input/Logic
Input
In host mode (HIF set LOW):
Serial digital data output for SPI serial host interface. Active-high output.
In non-host mode (HIF set HIGH):
Set LOW. Gennum recommends using a weak pull-down resistor (~50kΩ).
30
SDI
Input/Logic
Input
In host mode (HIF set LOW):
Serial digital data input for SPI serial host interface. Active-high input.
In non-host mode (HIF set HIGH):
Set LOW. Gennum recommends using a weak pull-down resistor (~50kΩ).
31
VEE_CP
Power
Most negative power supply connection for the internal
charge pump. Connect to GND.
32
VCC_CP
Power
Most positive power supply connection for the internal charge pump.
Connect to 3.3V or 2.5V
−
Center Pad
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Data Sheet
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June 2011
−
Ground pad on bottom of package. Connect to GND.
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1.3 Default Start-up Settings
The GS1675 has some functions that are not accessible via direct pin control, and are
only accessible through the host interface registers. These functions have an internal
pull-up or pull-down resistor that sets the default logic level or start-up state, if it is not
already set by a pin.
If the user wishes to override these logic levels, the associated bit should be programmed
within the PIN_OR_1 register (pin override register) at address 0x0C. The logic values
within the PIN_OR_1 register become active when the user sets the Pin Override Enable
bit to HIGH within that same register.
Table 1-2 shows:
1. The default logic state set by the internal pull up or pull down resistors.
2. The default values within the Pin Override register upon reset.
Table 1-2: GS1675 Default Start-up Settings
Default State set by
Internal Resistors
Default State within
the Pin Override
Register
0:0
0:0
Bypasses the reclocker stage when set HIGH.
0
0
When set HIGH, this bit automatically bypasses the
reclocker stage when the PLL is not locked to a
supported rate.
0
0
When set HIGH, the standard is automatically detected
from the input data rate.
1
0
None
0:0
Floating
Ground
Mutes the DDO0/DDO0 and DDO1/DDO1 (if data is
selected) outputs when LOW.
1
0
Disables the DDO1/RCO and DDO1/RCO outputs when
LOW.
0
0
HIGH = DATA
LOW = CLOCK
0
0
Name
DDI_SEL[0:1]
BYPASS
AUTOBYPASS
AUTO/MAN
SS0, SS1
KBB
DATA_MUTE
DDO1_DISABLE
DATA/CLOCK
Description
Selects one of two serial digital input signals for
processing. DDI0 is selected by default.
When AUTO/MAN is set HIGH, SS[1:0] are outputs
displaying the data rate to which the PLL has locked.
Therefore, they will not have default values.
Controls the loop bandwidth of the PLL.
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2. Electrical Characteristics
2.1 Absolute Maximum Ratings
Parameter
Value
Supply Voltage
-0.5 to +3.6VDC
Input ESD Voltage
4kV
Storage Temperature Range
-50ºC < TA < 125ºC
Operating Temperature Range
-40ºC to 85ºC
Input Voltage Range
-0.3 to (VCC + 0.3) VDC
Solder Reflow Temperature
260ºC
2.2 DC Electrical Characteristics
Table 2-1: DC Electrical Characteristics
Parameter
Supply Voltage
Power (DDO1/RCO disabled, minimum
output swing)
Symbol
VDD
P
Power (DDO1/RCO enabled, minimum
output swing)
Power in Power-down mode
Conditions
Min
Typ
Max
Units
3.3V
3.135
3.3
3.465
V
2.5V
2.375
2.5
2.625
V
VDD = 3.3V
−
250
−
mW
VDD = 2.5V
−
180
−
mW
VDD = 3.3V
−
300
−
mW
VDD = 2.5V
−
210
−
mW
VDD = 3.3V
−
40
−
mW
30
−
mW
VDD = 2.5V
Serial Input Termination
−
Differential
80
100
120
Ω
Serial Output Termination
−
Differential
80
100
120
Ω
Serial Input Common Mode Voltage
−
−
1.6
−
VDD
V
Serial Output Common Mode Voltage
−
−
−
VCC(ΔVOD
/2)
−
V
VIL (2.5V operation)
−
VOUT≤VOL, max
-0.3
−
0.7
V
VOUT≤VOL, max
-0.3
−
0.8
V
VIL (3.3V operation)
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Table 2-1: DC Electrical Characteristics (Continued)
Parameter
Symbol
Conditions
−
VIH (2.5V operation)
VIH (3.3V operation)
Min
Typ
Max
Units
VOUT≥VOH, min
1.7
−
VDD
+0.3
V
VOUT≥VOH, min
2
−
VDD
+0.3
V
IIN
−
VIN = 0V or VIN = VDD
−
−
+/-10
μA
VOL (2.5V operation)
−
VDD = min, IOL = 100μA
−
−
0.4
V
VDD = min, IOL = 100μA
−
−
0.4
V
VDD = min, IOH = -100μA
2.1
−
−
V
VDD = min, IOH = -100μA
VDD
-0.4
−
−
V
2.5V operation
−
350
−
mV
3.3V operation
−
350
−
mV
VOL (3.3V operation)
−
VOH (2.5V operation)
VOH (3.3V operation)
−
Hysteresis Voltage (SPI inputs)
NOTE: guaranteed by simulation.
2.3 AC Electrical Characteristics
Table 2-2: AC Electrical Characteristics
Parameter
Serial Input Data Rate
(for reclocking)
Symbol
DRSDO
Serial Input Data Rate
(bypass)
Conditions
Min
Typ
Max
Units
Notes
−
0.27
−
1.485
Gb/s
−
−
DC
−
1.485
Gb/s
−
−
−
−
10
MHz
−
2000
mVp-pd
−
SPI Operating Speed
−
Input Voltage Swing
ΔVSDI
Set ATTEN_EN = 1 for
ΔVSDI>1Vpp
100
Output Voltage Swing
ΔVOD
default
300
400
500
mVp-pd
−
see DRIVER_1 register
(0x01) addresses 8 & 9 in
3.14.14 Host Register
Map.
600
800
1000
mVp-pd
−
LOW
Recommended setting for 0 to 10
inches of FR4
−
MED
Recommended setting for 10 to 20
inches of FR4
−
HIGH
Recommended setting for >20 inches
of FR4
−
Input Trace Equalization
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Data Sheet
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Table 2-2: AC Electrical Characteristics (Continued)
Parameter
Output De-Emphasis
Input Jitter Tolerance
Loop Bandwidth
Symbol
−
−
BWLOOP
Conditions
Min
Typ
Max
Units
Notes
OFF - 0
−
0
−
dB
−
ON - 0
−
0
−
dB
−
ON - 1
−
0.7
−
dB
−
ON - 2
−
1.3
−
dB
−
ON - 3
−
2
−
dB
−
ON - 4
−
2.6
−
dB
−
ON - 5
−
3.3
−
dB
−
ON - 6
−
4
−
dB
−
ON - 7
−
4.7
−
dB
−
0.8
−
−
UI
−
KBB = VCC
−
170
−
kHz
−
KBB = FLOAT
−
340
−
kHz
−
KBB = GND
−
680
−
kHz
−
KBB = VCC
−
0.875
−
MHz
−
KBB = FLOAT
−
1.75
−
MHz
−
KBB = GND
−
3.5
−
MHz
−
square-wave modulated
jitter
(270Mb/s)
BWLOOP
(1485Mb/s)
PLL Lock Time (asynchronous)
talock
−
−
0.5
1
ms
−
PLL Lock Time (synchronous)
tslock
CLF = 47nF, SD/HD = 0
−
0.5
4
μs
−
CLF = 47nF, SD/HD = 1
−
5
10
μs
−
KBB = FLOAT
−
0.01
−
UI
−
−
0.03
−
UI
−
20% to 80% (400mV
swing)
−
65
−
ps
−
20% to 80% (800mV
swing)
−
80
−
ps
−
Serial Data Output Jitter Intrinsic
(DDO0)
tOJ(270MB/s)
PRN 2^23-1 test pattern
tOJ(1485MB/s)
KBB = FLOAT
PRN 2^23-1 test pattern
Output Rise/Fall Time
tr/f
Output Rise/Fall Time Mismatch
−
−
−
−
15
ps
−
Eye Cross Shift
−
percentage of signal
amplitude
−
−
5
%
−
Power Supply Noise Rejection
−
50 - 100Hz
−
100
−
mVp-p
−
100Hz - 10MHz
−
40
−
mVp-p
−
10MHz - 1.485GHz
−
10
−
mVp-p
−
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Data Sheet
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June 2011
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3. Functional Description
The GS1675 is a multi-standard reclocker for serial digital SDTV signals operating at
270Mb/s, and HDTV signals operating at 1.485Gb/s, 1.485/1.001Gb/s.
3.1 Serial Data Input
The GS1675 features two differential input buffers.
The serial data input signal is connected to the DDI0/DDI0 and DDI1/DDI1 input pins of
the device.
Input signals can be single-ended or differential, DC or AC-coupled.
The input circuit is self-biasing, to allow for simple AC or DC-coupling of input signals to
the device.
The serial digital data inputs are also compatible when DC-coupled with LVPECL or
CML differential outputs from crosspoint switches which operate from 3.3V or 2.5V
supplies. This includes but is not limited to the GS1674 Equalizer.
3.2 Modes of Operation
The GS1675 has two modes of operation: Legacy Mode (HIF = HIGH) and SPI Mode (HIF
= LOW).
In Legacy Mode, chip functions are controlled via pins only, and offers limited control of
input equalization.
In SPI mode, access is gained to extended digital controls like: Bypass, Autobypass,
Auto/Manual selection, Control status inputs or outputs, changes to KBB settings, as well
as access to additional features such as LOS adjustment, polarity invert, auto-mute, etc.
3.3 2:1 Input Mux
The GS1675 incorporates a 2:1 input mux, which allows the connection of two
independent streams of video/data. There are two differential inputs (DDI[1:0] /
DDI[1:0]). The active channel can be selected via the DDI_SEL[1:0] registers as shown in
Table 3-1.
Table 3-1: Input Selection Table
DDI_SEL[1:0]
Selected Input
00
DDI0*
01
NOT VALID
10
NOT VALID
11
DDI1
* Power-up default
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Active circuitry associated with the input buffers and trace EQ can only be turned on for
the selected input. Inputs which are not selected have their input buffers and trace EQs
turned OFF to save power. Unused inputs can be either left floating, or tied to VCC.
3.4 Crystal Buffer
The GS1675 features a crystal buffer supporting a Gennum recommended external
27MHz crystal. The GS1675 requires an external 27MHz reference clock for correct
operation. This reference clock is generated by connecting a crystal to the XTAL- and
XTAL+ pins of the device.
Alternately, a 27MHz external clock source can be connected to the XTAL- pin of the
device, while the XTAL+ pin should be left floating.
3.5 LOS (Loss Of Signal) Detection
The LOS (Loss Of Signal) status pin is an active-high output that indicates when the serial
digital input signal selected at the 2:1 input mux is invalid. In order for this output to be
asserted, transitions must not be present for a period of tLA = 5 - 10μs. After this output
has been asserted, LOS will de-assert within tLD = 0 - 5μs after the appearance of a
transition at the DDIx input. See Figure 3-1.
This signal is HIGH (signal lost), when the number of data edges within a window is
below a defined threshold. The output is automatically muted when LOS is detected.
This signal is LOW (signal valid), when the number of data edges within a window is
above a defined threshold. See Table 3-2.
Table 3-2: LOS Operation
LOS
Signal
HIGH
Invalid
LOW
Valid
The LOS function is operational for all operating modes of the device.
t LA
t LD
DATA
LOS
Figure 3-1: LOS Signal Timing
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The LOS mode can be selected using the host interface, in register TOP_1. The LOS
detector has two major modes. In legacy mode, a simple edge-based detector is used to
monitor the received signal at the output of the data slicer. Since the incoming signal has
undergone considerable gain by this point, the legacy detector can be more susceptible
to false de-assertion of LOS for unused channels which experience significant cross-talk
from adjacent active channels.
The new LOS detector uses a measure of both signal amplitude and duration to minimize
false detection of the impulse like signals that are characteristic of cross-talk. In this
mode, the signal is tapped off at the output of the equalizer stage, prior to the high gain
buffers.
The threshold setting within the detector can be adjusted to increase or decrease its
sensitivity. Higher sensitivity allows lower amplitude signals to be detected but also
increases the susceptibility to false de-assertion of LOS due to noise or cross-talk.
Therefore the lowest sensitivity acceptable for a given application should always be
used. See TOP_1 register, bits 8:7, in the host register map.
NOTE: It is also possible to have both legacy mode & threshold mode enabled together.
In this case, the reclocker must detect transitions within a set window, and the signal
amplitude must be greater than the setting for the LOS threshold.
3.6 Serial Digital Reclocker
The output of the Equalizer is fed to the reclocker. The function of the reclocker is to
re-time the input signal and to generate system clocks.
The reclocker operates at two data rates; 1.485Gb/s and 270Mb/s, and provides a
minimum input jitter tolerance of 0.8UI to square-wave-modulated jitter.
When there is no serial input signal, the internal clock maintains a frequency close to the
expected incoming data rate by locking to the external reference crystal.
3.7 Lock Detection
The lock detect block indicates, via the active-high LOCKED signal, when the device has
achieved lock to the incoming data stream.
The lock logic within the GS1675 includes a system that monitors the frequency and the
phase of the incoming data, as well as a monitor to detect harmonic lock.
Table 3-3: Lock Operation
LOCKED
Status
HIGH
Locked
LOW
Not locked
The LOCKED output signal is also available via the host interface.
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3.7.1 Lock Detect and Asynchronous Lock
The reference crystal is used to assist the PLL in achieving a short lock time. The lock
detection algorithm is a continuous process, which begins at device power up or after a
system reset, and continues until the device is powered down.
The asynchronous lock time is defined as the time it takes the device to lock when a
video signal is first applied to the serial digital inputs, or when the digital video signal
rate changes.
The synchronous lock time is defined as the time it takes the device to lock to a signal
which has been momentarily interrupted.
3.8 Serial Data Output
The GS1675 features two current-mode differential output drivers, each capable of
driving a maximum of 800mVpp differential, into an external 100Ω differential load.
Each of the GS1675's output buffers include two on-chip, 50Ω termination resistors.
3.8.1 Output Signal Interface Levels
The serial digital outputs of the GS1675 are compatible when DC-coupled with all
Gennum serial digital interface products that feature a differential LVPECL or CML
receiver designed for SDI applications and operate from 3.3V or 2.5V supplies. This
includes but is not limited to the GS1678 and the GS1679.
The serial digital data inputs are also compatible when DC-coupled with LVPECL or
CML differential outputs from crosspoint switches which operate from 3.3V or 2.5V
supplies. This includes but is not limited to the GS1674 equalizer.
3.8.2 Adjustable Output Swing
It is possible, via the host interface, to force the output swing to 400mVpp or 800mVpp
differential, when the outputs are terminated with 50Ω loads.
The default output swing upon power-up is 400mVpp differential.
3.9 Automatic and Manual Data Rate Selection
The GS1675 can be configured to manually lock to a specific data rate or automatically
search for and lock to the incoming data rate. The default configuration is AUTO mode.
This can be changed via the host interface.
In AUTO mode, the SS[1:0] registers become read only, and the bit pattern indicates the
data rate at which the PLL is currently locked to (or previously locked to). The search
algorithm cycles through the data rates and starts over if that data rate is not found (see
Figure 3-2).
A “search algorithm” cycles through the supported data rates until lock is achieved, as
shown in Figure 3-2 below.
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Power up
270Mb/s
1485Mb/s
*Note: the search algorithm does not necessarily begin with 270Mb/s.
Figure 3-2: GS1675 Automatic Mode Search Algorithm
In MANUAL mode, the SS[1:0] registers become read or write accessible, and the data
rate can be programmed. In this mode, the search algorithm is disabled and the GS1675's
PLL will only lock to the data rate selected in accordance with Table 3-4.
Table 3-4: Data Rate Indication/Selection Bit Pattern
SS[1:0]
Data Rate (Mb/s)
0
Reserved for 3G migration
1
270
2
1485 or 1485/1.001
3
Reserved for 3G migration
3.10 SD/HD Indication
The SD/HD signal indicates the output data rate of the device and can be connected to
the SD/HD input pin of the GS1678 and GS1679.
When this signal is HIGH, the data rate is 270Mb/s. This signal is LOW for all other data
rates.
This signal is also LOW when the device is operating in bypass mode (Auto-bypass and
User-bypass).
The SD/HD signal is LOW when the device is not locked.
3.11 Bypass Mode
In bypass mode, the GS1675 passes the data at the inputs, directly to the output. There
are two register bits that control the bypass function: BYPASS and AUTOBYPASS.
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The BYPASS bit is an active-high signal which forces the GS1675 into bypass mode for
as long as the bit is asserted HIGH.
The AUTOBYPASS bit is an active-high signal that places the GS1675 into bypass mode
only when the PLL has not locked to a data rate.
Table 3-5: Bypass Modes
Bypass
Autobypass
Device Operation
HIGH
X
Bypass Mode
LOW
HIGH
Bypass Mode if the PLL has not
locked to a data rate
LOW
LOW
Power-up default. Normal
Operation, part always tries to
lock to the incoming data
stream.
Note that if BYPASS is HIGH, this will override the AUTOBYPASS functionality.
When the GS1675's PLL is not locked and BYPASS = LOW and AUTOBYPASS = LOW, the
serial digital output DDO/DDO will produce invalid data.
The AUTOBYPASS function will bypass unsupported signal rates without producing bit
errors.
3.12 DVB-ASI
The GS1675 also reclocks DVB-ASI signals at 270Mb/s. In auto mode, the device will
automatically lock to the incoming 270Mb/s signal. In manual mode, the SS[1:0] bits
must be set to 01 (270Mb/s) to ensure proper operation.
3.13 Output Mute and Data/Clock Output Selection
The DATA_MUTE register is provided to allow muting of the primary serial digital data
output.
Setting DATA_MUTE = LOW will force the serial digital outputs DDO/DDO to mute
(statically latch HIGH) under all conditions and operating modes. DATA_MUTE will also
mute the secondary digital data output when DATA/CLOCK is set HIGH.
The DDO1_DISABLE register is provided to allow the second data/clock output to be
powered down.
When DDO1_DISABLE is set LOW, the serial digital clock outputs DDO1/RCO and
DDO1/RCO are muted and the driver is powered-down.
The DATA/CLOCK register is provided to allow the second output to emit a copy of the
reclocked serial data or the recovered clock. By default, this output will be set as DATA.
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Table 3-6: Configuration of GS1675 Output Drivers and Mute/Disable Pins
DATA_MUTE
DDO1_DISABLE
DATA/CLOCK
DDO0
DDO1/RCO
1
1
0
DATA
CLOCK
1
1
1
DATA
DATA
0
1
0
MUTE
CLOCK
0
1
1
MUTE
MUTE
1
0
X
DATA
Power down
0
0
X
MUTE
Power down
3.14 Host Interface
3.14.1 Introduction
The GS1675 offers a Serial Peripheral Interface (SPI) to access advanced features and
programmability. The polarity of the HIF pin tells the GS1675 whether or not the host
interface is active (HIF = 0) or in legacy mode (HIF = 1).
Using the host interface, it is possible to override the control pin settings, and such
settings will persist until the device has been powered-down and/or reset. The host
interface is capable of reading hard-wired pin configuration, pin override settings and
the values of all status monitoring pins.
There is an optional 3-state feature available in the Control Status Registers (CSR) that
puts the SPI SDO to high-impedance when it’s not being used (Register: TOP_1, bit: 2).
3.14.2 Legacy Mode & Startup
In legacy mode, basic configuration of the device is available at the pin level. In this
mode, register settings are automatically set to default so that the GS1675 is live at
power-up.
3.14.3 Host Interface Mode & Startup
In host interface mode, the user gains access to Control and Status Registers (CSRs) that
manage advanced features. In this mode, equalizer and de-emphasis settings are set
through the CSR.
The SPI control is functional at startup without need for a reset signal. However, to clear
the registers to their default state, a reset command is recommended via the SPI. This is
done by setting the R bit (reset) LOW in the command word. This will guarantee the CSR
will not start up in a random state.
The maximum operating speed of the SPI is 10MHz.
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3.14.4 Clock & Data Timing
The SPI signals are Serial Data Input (SDI), Serial Data Output (SDO), active-low Chip
Select (CS), and Serial Clock Input (SCK). The host interface operates in SPI Mode 0, i.e.
the SDI input will latch data in on the rising edge of SCK. The SDO data output will
transition on falling edges of SCK. Data is transmitted or received on the SPI port MSB
first LSB last.
SCK
CS
Cycle #
SDI
1
2
3
4
5
6
7
8
z
1
2
3
4
5
6
7
8
z
SDO
z
1
2
3
4
5
6
7
8
z
Figure 3-3: Data Clock Alignment
3.14.5 Single Device Operation
For applications with a single device or applications with multiple devices where daisy
chaining is not desired, the chain position bits C[6:0] should always be set to 0. As a
by-product of the daisy chaining feature, Read and Write operations experience a 32
SCK cycle latency from SDI to SDO. For more details on daisy-chaining, refer to
Section 3.14.8 on page 22.
rw
Read/
Write
0
0
R
A[4:0]
C N[6:0] = `0000000’
Reset
Address
Chain Position
Figure 3-4: 16-bit Command Format
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3.14.6 Write Operation - Single Device
A Write operation consists of a 16-bit command word and a 16-bit data word, followed
by 32 cycles with the slave SDI held HIGH. When writing to a single non-daisy chained
device, the following format should be used:
16 bit command
rw
R/W
0
R
A[4:0]
C[6:0] = 0
Reset
Address
Chain Position
0
CS
MOSI
Command
Command [15:0]
Data [15:0]
[15:0]
MISO
Data High 32 cycles
Command’ [15:0]
Data [15:0]
Figure 3-5: Single Device Write
1. At power-up, the device should be reset by setting the R bit LOW. A simple way to
accomplish a reset is to hold the slave SDI line LOW for an entire 64 cycle
communication.
2. For a Write operation, the r/w bit should be set to 0.
3. The 2nd and 3rd bits are reserved, and should be set to 0.
4. The R bit should always be set HIGH for a normal Write operation.
5. Refer to the Register Map for information on Address and Data bits.
6. The slave SDI line should be held HIGH for 32 cycles before de-asserting CS.
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3.14.7 Read Operation - Single Device
For Reading from a device the following format should be used:
16 bit command
rw
R/W
0
R
A[4:0]
C[6:0] = 0
Reset
Address
Chain Position
0
CS
MOSI
Command [15:0]
Data High 16 cycles
MISO
Data High 16 cycles
Data High 16 cycles
Command’ [15:0]
Data [15:0]
Figure 3-6: Single Device Read
1. For a Read operation, the r/w bit should be set to 1.
2. The 2nd and 3rd bits are reserved and should be set to 0.
3. The R bit should always be set HIGH for a normal Read Operation.
4. Data Out at the slave SDO will appear after holding the slave SDI line HIGH for 32
cycles.
5. The 16-bit data is now available on the slave SDO line.
Detailed timing diagrams for Write and Read can be seen in Figure 3-7 and Figure 3-8.
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R/W
0
0
t3
R
t1
A4
A3
t2
A2
A1
A0
t8
C6
C5
C4
R/W
0
t3
0
R
t1
A4
A3
t2
A2
A1
A0
t8
C6
C5
C4
C3
C3
C2
C2
C1
C0
C1
C0
D15 D14 D13 D12 D11
t6
t7
t8
Output hold time (15pF load)
CS_n HIGH after last HOST_CLK rising edge
Input data hold time
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t3
Input data setup time
D3
t2
D4
HOST_CLK duty cycle
D5
t1
D6
HOST_CLK period
D7
t0
D8
CS_n LOW before HOST_CLK rising edge
D9
Symbol
D10
Parameter
Table 3-7: SPI Interface Specifications
Figure 3-8: SPI Read Timing
32 cycles
delated
SDO
SDI
CS
SCK
t0
Figure 3-7: SPI Write Timing
32 cycles
delayed
SDO
SDI
CS
SCK
t0
D2
D0
R/W
0
0
t6
R/W
R
50% levels
Conditions
D1
0
A4
0
A3
R
A0
A3
C3
C2
D15 D14
C1
1.5
1.5
40
1.5
60
−
−
−
−
50
−
−
−
−
C0
D9
D8
D7
ns
ns
ns
ns
%
ns
ns
Units
D15 D14 D13 D12
D13 D12 D11 D10
−
C4
C0
−
C5
C1
100
C6
C2
−
A0
C3
−
A1
C4
1.5
A2
C5
Max
C6
Typ
Min
A4
A1
75% of
HOST_CLK
period
A2
D11
D6
D10
D5
D9
D4
D8
D3
D7
D2
D6
D1
D5
D0
t7
D4
D3
D2
D1
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D0
3.14.8 Daisy Chain Operation
For applications with multiple GS1675 devices, it is possible to daisy-chain up to 127
parts in serial. In this configuration, the first device SDI should be connected to the SPI
Master SDO. The serial data output of each device is then connected to the serial data
input of the following device, and so on. The last device's SDO connects to the Master's
SDI. Connecting devices in serial reduces the number of I/O ports required by the master
by removing the need for additional chip select lines.
SPI
Master
SCK
SDO
SDI
CS
SCK
SDI
SDO
CS
SPI
Slave
Chain Position 0
SCK
SDI
SDO
CS
SPI
Slave
Chain Position 1
SCK
SDI
SDO
CS
SPI
Slave
Chain Position 2
Figure 3-9: Daisy Chained SPI Bus
The position of each GS1675 device in the serial chain is referred to as its Chain Position,
with 0 corresponding to the first device. The Chain Position in the SPI command word is
decoded by each slave to know which device the master is talking to.
Each GS1675 slave is designed to output a replica of what it receives at its input after a
delay of 32 cycles. The Chain Position part of the command is decremented by one in the
duplicated command word at the output. Each device in the chain will only execute the
issued command if it verifies that the current chain position is set to 0.
A[4:0]
C[6:0]=N
Chain Position
A[4:0]
C[6:0]=N-1
Chain Position
-1
32 cycles
A[4:0]
32 cycles
SDI
SDO
GS1675
SDI
SDO
C[6:0]=N-2
Chain Position
-2
GS1675
Figure 3-10: Chain Position Decoding
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3.14.9 Read & Write Operation - Daisy Chained Devices
In a serial daisy chain configuration, Read and/or Write operations can be performed to
multiple devices in the chain via consecutive operations. Figure 3-11 below shows a
simple 3 device configuration.
MISO
MOSI
µC
SDI
SDO
GS1675
SDI
SDO
GS1675
SDI
SDO
GS1675
Figure 3-11: Three Devices in Daisy Chain Configuration
3.14.10 Writing to all Devices
When writing to all devices in the chain, a Write Command and corresponding Data is
required for each device. When the devices are being configured in the same way, all of
them will have the same command and data with the exception of the Chain Position
bits. This example assumes a 3-device daisy chain. A command is issued to the last
device in the chain first, although it is possible to talk to the devices in any order.
CS
MOSI
Command2 [15:0]
Data [15:0]
Command1 [15:0]
Data [15:0]
Command0 [15:0]
Data [15:0]
Data High 32 cycles
Chain Position = 2
Chain Position = 1
Chain Position = 0
MISO
Command0' [15:0]
Data [15:0]
Figure 3-12: Daisy Chain Write
1. The first command issued in time is the command for the last device in the chain
(chain position = 2). When the first device receives this command it will recognize
that the Chain Position is 2 and will not execute the command. It will duplicate the
command and data word at its output and decrement the Chain Position by one.
2. Consecutive commands are issued for each device in the chain as shown.
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3.14.11 Writing to a Single Device in the Chain
The following example shows how to write to a single device in a chain:
CS
MOSI
CommandN [15:0]
DataN [15:0]
Data High 32xN cycles
Data High 32 cycles
Chain Position = N
MISO
CommandN’ [15:0]
DataN [15:0]
Chain Position = N (N = 0 for first device in chain)
Figure 3-13: Daisy Chain Write to a Single Device
1. The command is issued to Chain Position N.
2. 32xN cycles are required to shift the command through N devices. The device at
chain position N executes the command.
3. 32 additional cycles are needed to complete the communication.
3.14.12 Reading from all Devices
To read from all devices in the chain, a Read command is issued for each device
consecutively. After each command, the data is held HIGH for 16 cycles. Once a device
recognizes that it is being talked to, it will output data from the register requested. A
clock needs to be applied to cycle the output data through all devices in the chain.
CS
SDI
Command 2
Data HIGH for
16 cycles
(Chain Position = 2)
Command 1
Data HIGH for
16 cycles
Command 0
Data HIGH for
16 cycles
(Chain Position = 0)
(Chain Position = 1)
SDO
CS
SDI
Data held
HIGH for 32x3
cycles
SDO
Command2’
Data2
Command1’
Data1
Command0’
Data0
Figure 3-14: Daisy Chain Read
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1. Read command is issued to the last device in the chain, followed by Read
commands to the lower chain positions.
2. Clock is applied to cycle the output data through the chain.
3. Command2’ refers to the altered or decremented Command2.
3.14.13 Reading from a Single Device in the Chain
The following example shows how to read from a single device in a chain:
CS
MOSI
CommandN [15:0]
Data High 16 cycles
Data High 32xN cycles
Data High 32x(K-N-1) cycles
Data High 16 cycles
Data High 16 cycles
CommandN’ [15:0]
DataN [15:0]
Chain Position = N
MISO
Chain Position = N (N = 0 for first device in chain)
Chain Length = K (K ≥ 1)
Figure 3-15: Daisy Chain Read from a Single Device
1. Read command and 16 cycles of data held HIGH are issued to chain position N.
2. 32xN cycles are applied with data HIGH to cycle the command through N devices
in the chain (NOTE: N is 0 for first device in chain). Device N executes the
command.
3. With K representing the total number of devices in the chain, 32x(K-N-1) cycles are
applied to bring the return data through the rest of the chain.
4. 16 additional cycles are applied until the data from device N is available on the
Master SDI.
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3.14.14 Host Register Map
Table 3-8: Host Register Map
Register
Name
Register
Address
Bit
Position
Access
Function
Default
Value
Valid
Range
Comments
EQ_1
0x00
15:10
RW
Reserved.
9
RW
Input Attenuation Enable
(ATTEN_EN)
0x0
0 or 1
Enable for input
signals above 1Vpp
differential
8
RW
Equalizer Offset Correction Enable
0x1
0 or 1
Recommend
always on
7
RW
Equalizer Gain Setting for DDI1
0x0
0 or 1
See supplementary
table below
6-5
RW
Unused
0x0
0 or 1
−
4
RW
Equalizer Gain Setting for DDI0
0x00
0 or 1
See supplementary
table below
3
RW
Equalizer Enable for DDI1
0x00
0 or 1
See supplementary
table below
2-1
RW
Unused
0x00
0 or 1
−
0
RW
Equalizer Enable for DDI0
0x00
0 or 1
See supplementary
table below
Equalizer Decode Logic
EQ_EN
EQ_GAI
N
EQ Setting
Recommended Trace Lengths
0
0
LOW
0 to 10 inches of FR4
0
1
LOW
0 to 10 inches of FR4
1
0
MED
10 to 20 inches of FR4
1
1
HIGH
20 or more inches of FR4
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Table 3-8: Host Register Map
Register
Name
Register
Address
Bit
Position
Access
DRIVER_1
0x01
15:10
RW
9
TOP_1
0x02
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Function
Default
Value
Valid
Range
Comments
Unused
0x0
0 or 1
−
RW
Amplitude Control for DDO1
0x1
0 or 1
0 = 800mV swing
1 = 400mV swing
8
RW
Amplitude Control for DDO0
0x1
0 or 1
0 = 800mV swing
1 = 400mV swing
7:5
RW
De-Emphasis Boost Amplitude
Control for DDO1
0x2
0x0 to
0x7
0x0 = Lowest
Setting
0x7 = Highest
Setting
4:2
RW
De-Emphasis Boost Amplitude
Control for DDO0
0x2
0x0 to
0x7
0x0 = Lowest
Setting
0x7 = Highest
Setting
1
RW
De-Emphasis Enable for DDO1
0x0
0 or 1
−
0
RW
De-Emphasis Enable for DDO0
0x0
0 or 1
−
15:9
RW
Reserved.
8:7
RW
LOS Threshold Adjust
0x0
0x0 to
0x3
0x0 = least
sensitive
0x3 = most
sensitive
6:5
RW
LOS Detection Method Select
0x0
0x0 to
0x2
0x0 = legacy edge
detectionmethod
0x1 = new signal
strength detection
method
0x2 = dual
detection method:
both must detect
signal present for
LOS to be LOW
4
RW
LOS Mute Enable
0x0
0 or 1
When enabled the
output will
automatically
mute if LOS is
HIGH
3
RW
Power Down
0x0
0 or 1
Chip powers down
when asserted
2
RW
Tri-State Enable for SPI Output
0x0
0 or 1
When enabled the
SPI SDO will be
high Z when CS is
not selected
1
RW
Crystal Buffer Disable
0x0
0 or 1
0 = Enabled
1 = Disabled
0
RW
Data Polarity Invert
0x0
0 or 1
0 = Not Inverted
1 = Inverted
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Table 3-8: Host Register Map
Register
Name
Register
Address
0X03 to 0X0B
PIN_OR_1
STATUS_1
Bit
Position
Function
Default
Value
Valid
Range
Comments
Reserved.
0x0C
0X0D
0X0E to 0X11
Access
15:13
RW
Unused
0x0
0 or 1
−
12
RW
DATA/CLOCK
0x0
0 or 1
−
11
RW
DDO1_DISABLE
0x0
0 or 1
−
10
RW
DATA_MUTE
0x0
0 or 1
−
9:8
RW
KBB
0x0
0x0,
0x2 or
0x3
Equivalent
settings:
0x0 = KBB to
ground
0x2 = KBB floating
0x3 = KBB to VCC
7
RW
SS1
0x0
0 or 1
−
6
RW
SS0
0x0
0 or 1
−
5
RW
AUTO/MAN
0x0
0 or 1
−
4
RW
AUTOBYPASS
0x0
0 or 1
−
3
RW
BYPASS
0x0
0 or 1
−
2
RW
DDI_SEL1
0x0
0 or 1
-See Table 3-1 for
valid values
1
RW
DDI_SEL0
0x0
0 or 1
0
RW
Pin Override Enable
0x0
0 or 1
When enabled,
input values will be
taken from this
register instead of
package pins
15:4
RO
Reserved.
−
−
−
3
RO
SD/HD
−
−
−
2
RO
LOCKED
−
−
−
1
RO
SS1
−
−
−
0
RO
SS0
−
−
−
Reserved.
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3.15 Device Power Up
In host mode (HIF pin tied LOW), control & status registers (CSRs) may start up in a
random state. There is a bit in the command word R which will reset the CSR when set
LOW.
In non-host mode (HIF pin tied HIGH), the HIF pin is used to trigger an internal reset
signal to place all registers in a deterministic, default state upon power-up.
In either host mode or non-host mode, other internal state machines (example: offset
correction and PLL) automatically recover from any state at start-up with no reset
required. It takes ~10μs for the device to lock after start-up.
3.16 Standby
The purpose of Standby mode is to allow operating power to be reduced when the
device's functionality is not required, and to have a rapid and simple transition to full
operation when the device is required.
In order to achieve this, the device can be powered-down by writing a ‘1’ to the ‘Power
Down’ bit located in register address 0x02.
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4. Typical Application Circuit
3
VCC2
JP5
2
VCO_SEL
1
R23
R24
422R
VCC2
267R
VDD_DIG
(Pin14)
VCC_VCO
(Pin9)
C31 C30
C33
10u
C32
1u 10n
C34
VCC_DDO1
(Pin19)
VCC_DDO0
(Pin23)
C20 C23 C27
10n
C13 C15 C16
10n DNP DNP
10n DNP DNP
VCC_CP
(Pin32)
C7
10n
220n
GND
GND
VEE_DDO0
(Pin24)
7
HIFb
4
CSb
SCK
SDO
SDI
27
28
29
30
8
1
2
C3
47n
C4
220n
DDI0
DDO0
DDI1
DDO1/RCO
DDI1
DDO1/RCO
GS1675
CS
SCK
SDO
SDI
XTAL-
22
21
Data Output 0
18
17
Data Output 1
ABM7-27.000MHZ-D2Y-T
26
Y1
R6
C1
25
XTAL+
NC
LF+
CP_CAP
SD/HD
LOS
LOCKED
18p
GND
1M
16
13
12
C2
SD/HD
LOS
LOCKED
18p
GND
10
15
20
24
31
GND
GND
DDO0
HIF
VEE_CP
(Pin31)
TAB
6
Data Input 1
DDI0
VEE_VCO
VSS_DIG
VEE_DDO1
VEE_DDO0
VEE_CP
3
5
Data Input 0
SPI
VEE_DDO1
(Pin20)
VDD_1P8
VCC_VCO
VDD_DIG
VCC_DDO1
VCC_DDO0
VCC_CP
U2
VSS_DIG
(Pin15)
11
9
14
19
23
32
VEE_VCO
(Pin10)
GND
Figure 4-1: GS1675 Typical Application Circuit
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5. Input/Output Circuits
VCC
5.55kΩ
12.96kΩ
25Ω
VCC
25Ω
DDI
VCC
25Ω
25Ω
DDI
Figure 5-1: High-speed Inputs (DDI0, DDI0, DDI1, DDI1)
VCC
2.5µA
VCC
1.4kΩ
VREF
IN
Figure 5-2: Low-speed Input with weak internal pull-up (HIF)
VCC
VCC
972Ω
OUT
Figure 5-3: Low-speed Outputs (LOCKED, LOS, SD/HD)
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VCC
VCC
VCC
50Ω
50Ω
DDO
DDO
Figure 5-4: High-speed Outputs (DDO1/RCO, DDO1/RCO, DDO0, DDO0)
VCC
VCC
EN
VCC
VCC
XTAL+
246Ω
XTALEN
Figure 5-5: High-speed Crystal Oscillator I/O (XTAL-, XTAL+)
VCC
IN
VCC
1kΩ
2.5µA
Figure 5-6: SPI Inputs (CS, SCK, SDI)
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VCC
VCC
1.4kΩ
VREF
2.5µA
VCC
Tgate
SDO
SPI SDO
tri-state
Logic
Figure 5-7: SPI Output (SDO)
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6. Package and Ordering Information
6.1 Package Dimensions
Detail A
3.300±0.050
Exp. DAP
5.000±0.050
Pin 1 dot
by marking
0.180 Typ.
0.
0
15
p.
Ty
0.500 Bsc
Pin #1 Identification
Chamfer 0.400 x 45°
3.300±0.050
Exp. DAP
5.000±0.050
0.000-0.100
0.240±0.050
Detail A
0.375±0.050
3.500
Ref.
Top View
Bottom View
0.750 ±0.050
0.000-0.050
0.203 Ref.
Side View
6.2 Recommended PCB Footprint
0.5
0.85
0.25
3.45
4.1 4.95 5.8
3.45
0.25
4.1
5.8
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Data Sheet
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June 2011
NOTE: All dimensions
are in millimeters.
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6.3 Packaging Data
Parameter
Value
Package Type
5mm x 5mm 32-pin QFN
Moisture Sensitivity Level
3
Junction to Case Thermal Resistance, θj-c
19.9°C/W
Junction to Air Thermal Resistance, θj-a (at zero
airflow)
34.9°C/W
Junction to Board Thermal Resistance, θj-b
12.5°C/W
Psi, ψ
0.5°C/W
Pb-free and RoHS Compliant
Yes
6.4 Marking Diagram
Pin 1
Indicator
HD-SDI
GS1675
XXXXE3
YYWW
GS1675 SD/HD SDI Reclocker
Data Sheet
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GS1675 - Package Mark
XXXX - Last 4 digits (excluding decimal)
of SAP Batch Assembly (FIN)
as listed on Packing Slip
E3 - Pb-free & Green Indicator
YYWW - Date Code
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6.5 Solder Reflow Profile
Temperature
60-150 sec.
20-40 sec.
260°C
250°C
3°C/sec max
217°C
6°C/sec max
200°C
150°C
25°C
Time
60-180 sec. max
8 min. max
Figure 6-1: Maximum Pb-free Solder Reflow Profile
6.6 Ordering Information
Part Number
Package
Temperature Range
GS1675
GS1675-INE3
Pb-free 32-pin QFN
-40°C to 85°C
GS1675
GS1675-INTE3
Pb-free 32-pin QFN
(250pc. tape and reel)
-40°C to 85°C
GS1675
GS1675-INTE3Z
Pb-free 32-pin QFN
(2.5k tape and reel)
-40°C to 85°C
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Revision History
Version
ECR
PCN
Date
Changes and/or Modifications
1
156399
–
June 2011
Added Host Register Map.
0
154128
–
May 2010
Converted to Data Sheet.
A
153741
–
April 2010
New document.
DOCUMENT IDENTIFICATION
CAUTION
DATA SHEET
ELECTROSTATIC SENSITIVE DEVICES
The product is in production. Gennum reserves the right to make changes to
the product at any time without notice to improve reliability, function or
design, in order to provide the best product possible.
DO NOT OPEN PACKAGES OR HANDLE EXCEPT AT A
STATIC-FREE WORKSTATION
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Phone: (886) 2-8732-8879
Fax: (886) 2-8732-8870
E-mail: [email protected]
Gennum Corporation assumes no liability for any errors or omissions in this document, or for the use of the circuits or devices described herein. The sale of
the circuit or device described herein does not imply any patent license, and Gennum makes no representation that the circuit or device is free from patent
infringement.
All other trademarks mentioned are the properties of their respective owners.
GENNUM and the Gennum logo are registered trademarks of Gennum Corporation.
© Copyright 2010 Gennum Corporation. All rights reserved.
www.gennum.com
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