LSI L64734 Tuner and satellite receiver chipset Datasheet

L64733/L64734
Tuner and Satellite
Receiver Chipset
Datasheet
The L64733/34 chipset is designed specifically to meet the needs of
satellite broadcast digital TV and is compliant with the European digital
video broadcast (DVB-S) standard and the technical specifications for
DSS systems. The chipset forms a complete “L-Band to bits” system.
A typical application of the L64733/34 chipset is satellite digital TV
reception in accordance with ETS 300 421. Figure 1 shows the
L64733/34 chipset satellite receiver implemented in a typical satellite
receiver set-top decoder box.
Figure 1
Block Diagram of Set-Top Decoder Box Using the L64733/34 Chipset
Optional
Optional
DRAM
256K x 16
Decryption
Engine
L64733/L64734 Chipset
/ 16
CO
[7:0]
Satellite In
RF Out
(Loop Through)
L64733
Transport
Demux
L64734
/ 2
Microprocessor
Data and
Address Bus
/ 8
8
/
High-Speed
Port
27 MHz
VCXO
/
Microprocessor
NTSC
PAL
S-Video
PAL / NTSC
Encoder
8
Audio
Oversampling
Clock
CCIR601VIDEO
/
8
Audio/Video
Decoder
L-Speaker
R-Speaker
PCM
Audio DAC
Audio/Video PES
PCM AUDIO
/
3
64/32
SDRAM
256K x 64
256K x 32
The L64733/34 chipset consists of the L64734 Satellite Receiver IC, the
L64733 Tuner IC, and an on-chip synthesizer. Figure 2 shows a simplified
block diagram of this chipset.
August 2000
Copyright © 1999, 2000 by LSI Logic Corporation. All rights reserved.
1
Figure 2
L64733/34 Simplified Block Diagram
Select
RF Input
RF Output
L64733
RF
Switch
Synthesizer,
Mixer,
DownConverter
Control Signals
Baseband
Filter
IOUT
QOUT
L64734
Control
Modules for
Synthesizer
and Filter
Dual ADC
Demodulator
Host
Microcontroller
Error
Correction
Microcontroller
Interface
Descrambler
MPEG Output
The L64734:
•
generates control signals for the L64733 synthesizer, using
frequency information programmed into the L64734 configuration
registers
•
controls the programming of the low-pass filters on the L64733
•
generates dual AGC control voltages for the two-stage automatic
gain control on the L64733 IC.
The L64733 Tuner IC directly down-converts the satellite signal from
L-band to baseband.
2
L64733/L64734 Tuner and Satellite Receiver Chipset
Figure 3 shows a more detailed chipset block diagram.
Figure 3
Detailed Chipset Block Diagram
L64733
÷
by 8
Xtal
Osc
Phase
Detect.
Charge
Pump
4–7.26 MHz
RF In
RF
Switch
RF Out
Quadrature
Down-Converter
Amp
X2
VCO
90°
Fc
2
IOUT
FLCLK
QOUT
AGC2
AGC1
2
2
CPG
2
MOD
PLLIN
PSOUT 2
DualModulus
Prescaler
FDOUB
INSEL
Tank
Circuit
To External
Loop Filter
L64734
AGC
Control
Synthesizer Control Module
Filter
Control
Module
Carrier
Loop Control
BPSK/QPSK
Demodulator
Timing Loop
Control
DEMI
Interpolator/Decimation
Filter
Dual
ADC
Matched
Filter
Output
Control
1/T
DEMQ
Microcontroller Data and Address Bus
Clk
(from L64734
on-chip PLL) FEC Decoder Pipeline
External Microcontroller Interface
Microcontroller Data and Address Bus
Channel
Output
(MPEG-2
Transport
Stream)
Descrambler
ReedSolomon
Decoder
Convolutional
Deinterleaver
ReedSolomon
Synchronizer
Viterbi
Decoder
Viterbi
Synchronizer
L64733/L64734 Tuner and Satellite Receiver Chipset
3
The L64733 directly accepts the RF In L-Band signal input from the
satellite LNB feed. The L64733 handles a fully loaded raster of
transponder signals from 925 MHz to 2175 MHz. RF In is internally
matched to 75 Ω, and except for a DC-blocking capacitor, requires no
matching network between the cable connector and the L64733 input
pins. The L64733 uses the L64734 INSEL signal to select the
appropriate RF function (Normal or Loop-Through mode).
The RF signal goes to a variable gain stage, which is controlled by the
L64734 AGC1 signal. The L64734 adjusts AGC1 in conjunction with
AGC2 to maximize the SNR of the RF signal while maintaining proper
levels at the baseband outputs (IOUT and QOUT). The signal then goes
to two mixers in the quadrature demodulator. The mixers are fed with
local oscillator signals that are offset by 90 degrees from one another.
The quadrature demodulator performs a direct frequency conversion of
the RF signal to baseband while splitting the signal into quadrature I and
Q signal paths.
The baseband signals pass through a pair of variable-gain amplifiers that
are controlled by the AGC2 pin, which, in turn is controlled by the
L64734. The signals are then filtered through a pair of 7th-order filters
for anti-aliasing. The filter shape is 7th-order Butterworth, followed by a
single-pole delay equalizer. The filter cut-off frequency, which is
controlled by the L64734 FLCLK signal, is related to the baud rate. The
filtered baseband output signals go to the differential output stages at
IOUTp, IOUTn, QOUTp and QOUTn.
The baseband outputs of the L64733 go to the L64734, where they are
digitized by the analog-to-digital converter (ADC). The outputs then go to
a BPSK/QPSK demodulator, where they are filtered. The demodulator
then sends them to the L64734 FEC decoder pipeline, which outputs an
MPEG-2 transport stream.
The frequency synthesizer functionality is split between the L64733 and
L64734. The Synthesizer Control Module resides on the L64734; it
generates control signals for the L64733 Tuner IC frequency synthesizer.
The Synthesizer Control Module also contains some of the
programmable counters that are part of the synthesizer feedback loop.
The L64733 contains many of the analog functions of the frequency
synthesizer, as well as the RF local oscillator and crystal reference
oscillator. Tuning oscillator signals are generated for the mixers in the
4
L64733/L64734 Tuner and Satellite Receiver Chipset
range from 925–2175 MHz, with a 0.5 MHz step size when using a
4-MHz crystal reference. The on-chip VCO tuning frequency is 543 MHz
to 1088 MHz. To tune channels from 925–1086 MHz, the L64734
disables the frequency doubler (X2 block) on the L64733. To tune
channels from 1086 MHz to 2175 MHz, the L64734 enables the
frequency doubler. The VCO requires an external resonant tank circuit,
which includes varactor diodes to vary the frequency of oscillation.
The VCO signal goes to the Prescaler block before it is passed to the
L64734 differentially through the PSOUTp and PSOUTn pins. The
L64734 MODp and MODn differential signals control the divider ratio for
the Prescaler block. The L64734 dynamically changes the divide ratio to
ensure that the tuning step size is not affected by the divider. The
L64734 contains programmable counters to further divide the signal in
frequency before the signal is fed back to the L64733 through the PLLINp
and PLLINn pins. The crystal reference oscillator frequency is divided by
eight, then fed to the phase detector. The phase detector generates a
current signal proportional to the difference in phase between PLLINp,
PLLINn, and the divided crystal frequency. A charge pump circuit (which
controls pins CP, FB) and an external transistor (to buffer the L64733
against the tuning voltage of 28 V) generate the current. The current is
filtered, fed through a discrete loop filter, and converted to a tuning
voltage that drives the external varactor diodes for the VCO tank circuit.
A complete frequency controlled loop is formed, and the VCO frequency
can be varied by changing the frequency divider ratios in the L64734
registers. See Figure 7 on page 22 for more details regarding the
external circuitry for the VCO, crystal oscillator, charge pump, tank
circuitry, and entire frequency-controlled loop.
The chipset provides maximum integration and flexibility for system
designers at a minimum cost. The number of external components
required to build a system is minimal because the synthesizer, variable
rate filters, and clock and carrier loops are all integrated into the two
devices.
L64733/L64734 Tuner and Satellite Receiver Chipset
5
Features and Benefits
System Features
•
Direct down-conversion
•
Integrated programmable cut-off low-pass filters for variable-rate
operation
•
Dual AGC for optimizing performance with respect to intermodulation
and noise
•
Integrated synthesizer
•
Integrated quadrature amplitude and phase imbalance compensation
•
RF loop-through
Chipset Features
6
•
Supports DVB and DSS system specifications
•
BPSK/QPSK demodulation rates from 1 to 45 Mbaud
•
Matched filter (square root raised cosine filter with roll-off factor of
20% or 35%)
•
Anti-aliasing filters for operation from 1 to 45 Mbaud without
switching external SAW filters or the need for low-pass filters
•
On-chip digital clock synchronization
•
On-chip digital carrier synchronization, featuring a frequency sweep
capability for signal acquisition
•
Auto-acquisition demodulator mode and tuner control through an
on-chip microcontroller
•
Integrated Phase-Locked Loop (PLL) for clock synthesis, allowing the
use of a fundamental mode crystal
•
Fast channel switching mode
•
Power estimation for AGC control
•
Programmable Viterbi decoder module for rates 1/2, 2/3, 3/4, 5/6,
6/7, 7/8
•
Reed-Solomon decoder (204/188), (146/130)
•
Auto-synchronization for Viterbi decoder
L64733/L64734 Tuner and Satellite Receiver Chipset
•
Programmable synchronization for deinterleaver, Reed-Solomon
decoder, and descrambler
•
Bit error monitoring for channel performance measurements
•
Deinterleaver (DVB and DSS)
•
Serial host interface compatible with the LSI Logic Serial Control bus
interface
•
Power-down mode
•
On-chip dual differential 6-bit ADCs
•
Supports Synchronous Parallel Interface protocol for FEC data output
Chipset Interconnections
Figure 4 shows the interconnections between the L64733 and L64734.
Figure 4
Chipset Interconnection Diagram
L64733
L64734
Control
Signals
PLLINp
PLLINn
MODp
MODn
FDOUB
FLCLK
INSEL
AGC1
AGC2
CPG1
CPG2
XTLOUT
PLLINp
PLLINn
MODp
MODn
FDOUB
FLCLK
INSEL
AGC1
AGC2
XCTR[0]
XCTR[1]
XOIN
Control
Signals
Prescaler
Signals
PSOUTp
PSOUTn
PSOUTp
PSOUTn
Prescaler
Signals
Channel Data
Signals
IOUTp
IOUTn
QOUTp
QOUTn
IVINp
IVINn
QVINp
QVINn
Channel Data
Signals
L64733/L64734 Tuner and Satellite Receiver Chipset
7
L64733 Signal Descriptions
This section describes the L64733 signals. Figure 5 shows the interface
diagram of the L64733. Names of signals that are active-LOW are
designated with an “n” suffix (for example, ERROROUTn). Names of
differential signals are designated with a “p” suffix for the noninverting
side (for example, QOUTp), and with an “n” suffix for the inverting side
(for example, QOUTn).
Figure 5
L64733 Interface Diagram
RFINn
RF
Signals
RFINp
RFOUT
Oscillator
Signals
Channel Data
Signals
Prescaler
Signals
XTLn
CFLT
TANKn
TANKp
VRLO
XTLp
XTLOUT
IOUTn
IOUTp
QOUTn
QOUTp
PSOUTn
PSOUTp
AGC1
AGC2
CPG1
CPG2
FDOUB
FLCLK
IDCn
IDCp
INSEL
MODn
MODp
PLLINn
PLLINp
QDCn
QDCp
CP
FB
Control
Signals
Charge Pump
Signals
As shown in Figure 5, the L64733 has the following major interfaces:
8
•
RF
•
Oscillator
•
Control
•
Channel Data
•
Prescaler
•
Charge Pump
L64733/L64734 Tuner and Satellite Receiver Chipset
The following signal descriptions are listed according to the major
interface groups. Within each group, the signals are described in
alphabetic order.
RF Signals
The L64733 can accept an RF input signal and loop it through to RFOUT.
This is controlled by an on-chip RF switch.
RFINn, RFINp RF Input
Input
The RFIN differential signals form the 75 Ω input.
Connect the RFINp signal through a series 100 pF
capacitor to a 75 Ω F video connector and the RFINn
signal through a series 75 Ω resistor and 100 pF
capacitor to ground.
RFOUT
RF Output
Output
The RFOUT signal is a 75 Ω output that is active when
the INSEL input is deasserted. When active, the signal at
RFOUT is a copy of the RFIN signal.
Oscillator Signals
The L64733 has two internal oscillators: a crystal oscillator and a tank
oscillator.
CFLT
Bias Voltage Bypass
Bidirectional
See Figure 7 on page 22 for information on how to
connect the CFLT pin.
TANKn, TANKp
Oscillator Tank Port
Input
See Figure 7 on page 22 for information on how to
connect the TANKp and TANKn pins.
VRLO
Local Oscillator Regulator Bypass
Bidirectional
See Figure 7 on page 22 for information on how to
connect the VRLO pin.
XTLn, XTLp
Crystal Oscillator Port
Input
Connect the XTLp and XTLn pins as shown in Figure 7
on page 22.
L64733/L64734 Tuner and Satellite Receiver Chipset
9
XTLOUT
Crystal Out
Output
This signal provides a buffered clock reference frequency
for driving the L64734 XOIN pin.
Control Signals
The following signals, some of which are generated by the L64734 IC,
control the mode of operation of the L64733 IC.
AGC1
Automatic Gain Control 1
Input
The AGC1 signal is a high-impedance input from the
L64734; it controls the RF AGC circuitry. The AGC1
voltage range is from 0.5 V to 4.8 V.
AGC2
Automatic Gain Control 2
Input
The AGC2 signal is a high-impedance input from the
L64734; it controls RF AGC circuitry.
CPG[2:1]
Charge Pump Gain
The CPG[2:1] signals set the charge pump gain
according to the following table.
Input
Charge Pump Current (typ), mA
10
CPG1
CPG2
FB HIGH
FB LOW
0
0
0.1
−0.1
0
1
0.3
−0.3
1
0
0.6
−0.6
1
1
1.8
−1.8
FDOUB
Frequency Doubler
Input
When the FDOUB signal is asserted, the L64733 local
oscillator frequency is internally doubled and fed to the
mixers. When the FDOUB signal is deasserted, the
oscillator frequency is not doubled before being fed to the
mixers.
FLCLK
Filter Clock
Input
The FLCLK signal is a low-amplitude, self-biased clock
input. The frequency of the FLCLK signal multiplied by 16
is the baseband filter’s −3 dB frequency.
IDCn, IDCp
I-Channel DC Offset Correction
Input
Connect a 0.1 µF (or larger) capacitor between the IDCp
and IDCn signals.
L64733/L64734 Tuner and Satellite Receiver Chipset
INSEL
RF Port Input Select
Input
When the INSEL signal is asserted, the L64733 is in
normal mode. When the INSEL signal is deasserted, the
L64733 is in Loop-Through mode. In this mode, the RFIN
signal is looped through to the RFOUT signal, and the
L64733 local oscillator is shut off.
MODn, MODp Prescaler Modulus
Input
The MOD differential signals form a PECL input that sets
the prescaler modulus. When the MODp signal is positive
with respect to the MODn signal, the prescaler modulus
is set to 32 (divide by 32). When the MODn signal is
positive with respect to the MODp signal, the prescaler
modulus is set to 33 (divide by 33).
PLLINn, PLLINp
Phase Detector
Input
The PLLIN differential signals form the phase detector
input and are connected to the L64734 PLLINp and
PLLINn output signals. See the L64734 PLLINp and
PLLINn descriptions in the subsection entitled
“Synthesizer Control Interface” on page 19.
QDCn, QDCp Q-Channel DC Offset Correction
Input
Connect a 0.1 µF (or larger) capacitor between the QDCp
and QDCn signals.
Channel Data Signals
This section describes the channel data signals from the L64733 to the
L64734.
IOUTn, IOUTp I-Channel Baseband Data
Output
The IOUT differential signals form the in-phase data
provided to the L64734.
QOUTn, QOUTp
Q-Channel Baseband Data
Output
The QOUT differential signals form the quadrature-phase
data provided to the L64734.
L64733/L64734 Tuner and Satellite Receiver Chipset
11
Prescaler Signals
The following signals are the prescaler outputs from the L64733 to the
L64734.
PSOUTn, PSOUTp
Prescaler
Output
These differential signals are the L64733 prescaler
outputs. The programmable counters on the L64734 are
clocked on the rising edge of the PSOUT signal.
Charge Pump Signals
The following signals are outputs from the L64733 charge pump.
12
CP
Charge Pump
Output
Connect the CP signal as shown in Figure 7 on page 22.
FB
Feedback Charge Pump Transistor Drive
Output
Connect the FB signal as shown in Figure 7 on page 22.
L64733/L64734 Tuner and Satellite Receiver Chipset
L64734 Signal Descriptions
This section provides detailed information on the L64734 signals.
Figure 6 shows the interface diagram of the L64734.
Figure 6
L64734 Interface Diagram
IVINp
IVINn
QVINp
QVINn
IBYPASS[5:0]
QBYPASS[5:0]
Channel
Interface
CLK
XOIN
XOOUT
Channel Clock
Interface
LCLK
LP2
PLLAGND
PLLVDD
PLLVSS
PCLK
PLL
Interface
IDDTn
RESET
XCTR_IN
XCTR[3:0]
Control Signals
Interface
AGC Control
Interface
AGC1
AGC2
Tuner Control
Interface
FLCLK
INSEL
BCLKOUT
CO[7:0]
COEn
DVALIDOUT
ERROROUTn
FSTARTOUT
INTn
SADR[1:0]
SDATA
SCLK
FDOUB
PSOUTp
PSOUTn
MODp
MODn
PLLINp
PLLINn
VREF_LVDS
RESO_LVDS
VREFP
VREFN
ADCVSSI
ADCVSSQ
ADCVDDI
ADCVDDQ
VMID
Channel Data
Output Interface
Microcontroller
Interface
Synthesizer
Control
Interface
ADC
Interface
As shown in Figure 6, the L64734 has the following major interfaces:
•
Channel
•
Channel Clock
•
PLL
•
Control Signals
•
ADC
L64733/L64734 Tuner and Satellite Receiver Chipset
13
•
AGC Control
•
Channel Data Output
•
Microcontroller
•
Synthesizer Control
•
Tuner Control
The following signal descriptions are listed according to the major
interface groups.
Channel Interface
The Channel Interface is the input path to the L64734 satellite receiver.
IVIN and QVIN are the I and Q streams, respectively, from the satellite
tuner circuit. The CLK signal strobes in the data signals.
IBYPASS[5:0] I Channel Data
Input
The IBYPASS[5:0] signals form the digital I channel data
input bus, which supplies the I Stream to the L64734
when the ADC is bypassed. Bypass is controlled through
the setting of particular register bits in the L64734.
IVINn, IVINp
I Channel Data
Input
These differential signals form the analog received I
channel data input bus, which supplies the I stream to the
L64734.
QBYPASS[5:0]
Q Channel Data
Input
The QBYPASS[5:0] signals form the digital received
Q channel data input bus, which supplies the Q Stream
to the L64734 when the ADC is bypassed. Bypass is
controlled through the setting of particular register bits in
the L64734.
QVINn, QVINp
Q Channel Data
Input
The QVINn and QVINp differential signals form the
analog received Q channel data input bus, which supplies
the Q stream to the L64734.
14
L64733/L64734 Tuner and Satellite Receiver Chipset
Channel Clock Interface
The Channel Clock Interface consists of the clock and crystal oscillator
signals.
CLK
Input Clock
Input
This functionality has been assigned to the XOIN pin.
XOIN
Crystal Oscillator In
Input
The XOIN pin is used for a crystal oscillator or external
reference clock input. A 15 MHz crystal is normally
connected to the XOIN pin. This pin can also be driven
by the XOOUT pin from L64733. When using an external
ADC to strobe bypass data into the L64734, connect the
clock input to this pin.
XOOUT
Crystal Oscillator Out
This is the crystal oscillator output pin.
Output
Phase-Locked Loop (PLL) Interface
The internal PLL generates the signals to operate the ADC, demodulator,
and FEC modules.
LCLK
Decimated Clock Output
Output
The L64734 internal clock generation module generates
the LCLK signal. LCLK is derived by dividing CLK by the
value of the CLK_DIV2 register parameter.
LP2
Input to VCO
Input
The LP2 signal is the input to the internal voltagecontrolled oscillator. It is normally connected to the output
of an external RC filter circuit.
PCLK
PLL Clock Output
Output
The L64734 internal PLL clock synthesis module
generates the PCLK signal. The PLL is driven by the
reference crystal connected between the XOIN and
XOOUT pins. The PLL clock synthesis module can be
configured to generate a PCLK rate that is appropriate for
all data rates.
PLLAGND
PLL Analog Ground
Input
PLLAGND is the analog ground pin for the PLL module;
it is normally connected to the system ground plane.
L64733/L64734 Tuner and Satellite Receiver Chipset
15
PLLVDD
PLL Power
Input
PLLVDD is the power supply pin for the PLL module; it is
normally connected to the system power (VDD) plane.
PLLVSS
PLL Ground
Input
PLLVSS is the ground pin for the PLL module; it is
normally connected to the system ground plane.
Control Signals Interface
The Control Signals interface controls the operation of the L64734; it is
not associated with any particular interface.
16
IDDTn
Test
Input
The IDDTn pin is an LSI Logic internal test pin. Tie the
IDDTn pin LOW for normal operation.
RESET
Reset
Input
This active-HIGH signal resets all internal data paths.
Reset timing is asynchronous to the device clocks. Reset
does not affect the configuration registers.
XCTR_IN
Control Input
Input
The XCTR_IN pin is an external input control pin. It is
sensed by reading the XCTR_IN register bit.
XCTR[3]
Control Output/Sync Status Flag
Output
This signal indicates the synchronization status for one of
three synchronization modules in the L64734 or the
XCTR[3] field in Group 4, APR 55. The modules are the
Viterbi decoder, Reed-Solomon deinterleaver (DI/RS),
and descrambler. For any of the three synchronization
outputs, asserting the XCTR[3] signal indicates that
synchronization has been achieved for the sync module
chosen using the SSS[1:0] register bits. When
deasserted, the signal indicates an out-ofsynchronization condition.
XCTR[2:0]
Control Output
Output
The XCTR[2:0] pins are external output control pins.
They are set by programming particular register bits.
XCTR[2] is mapped to CPG1, and XCTR[0] is multiplexed
with CPG2, when used with the L64733 Tuner IC. When
the on-chip serializer is used to generate a serial 2- or
3-wire protocol on the XCTR[2:0] pins, the mapping is
XCTR[2] = EN, XCTR[1] = SCL, and XCTR[0] = SDA.
L64733/L64734 Tuner and Satellite Receiver Chipset
Analog-to-Digital Converter (ADC) Interface
The ADC module converts the incoming IVIN and QVIN signals into an
internal 6-bit digital representation for processing. The following pins
support the ADC module.
ADCVDDI/Q
ADC Power
Input
These are the analog power supply pins for the ADC
module; they are normally connected to the system
power (VDD) plane.
ADCVSSI/Q
ADC Analog Ground
Input
These are the analog ground pins for the ADC module;
they are normally connected to the system ground plane.
VREFP
Reference Voltage, Positive
Input/Output
ADC reference voltage generated by the on-chip
bandgap-based generator. Bypass to GND using a
0.1 µF capacitor.
VREFN
Reference Voltage, Negative
Input/Output
ADC reference voltage generated by the on-chip
bandgap-based generator. Bypass to GND using a
0.1 µF capacitor.
VMID
Reference Voltage, Middle
Input/Output
ADC reference voltage generated by the on-chip
bandgap-based generator. Bypass to GND using a
0.1 µF capacitor.
AGC Control Interface
The AGC Control interface contains signals used for power control.
AGC1, AGC2 Power Control Signals
Output
The AGC1 and AGC2 signals are the positive Σ∆
modulated output used for power control. These signals
can each drive an external passive RC filter that feeds a
gain control stage for dual-stage AGC. For a single-stage
AGC, AGC1 can be used.
L64733/L64734 Tuner and Satellite Receiver Chipset
17
Channel Data Output Interface
The Channel Data Output interface is the output path from the L64734.
It is typically connected to the input of the transport demultiplexer in a
set-top decoder application.
BCLKOUT
Byte Clock Out
Output
This signal indicates valid data bytes on the CO[7:0] bus
when the L64734 is in Parallel Channel Output mode.
This signal cycles once every valid output data byte. It is
used by the transport demultiplexer to latch output data
from the L64734 at the BCLKOUT rate. Disregard the
BCLKOUT signal when the L64734 is in Serial Channel
Output mode.
CO[7:0]
Channel Data Out
Output
The CO[7:0] signals form the decoded output data port.
When the OF bit is 1 (Group 4, APR17), the L64734
operates in the Parallel Channel Output mode. In this
mode, the L64734 outputs the channel data as eight-bitwide parallel data on the CO[7:0] signals. In Serial
Channel Output mode (OF = 0), the L64734 outputs the
channel data as serial data on CO[0]. The data is latched
on every bit clock cycle. The chronological ordering in
Serial Channel output mode is: MSB oldest, LSB newest.
COEn
Channel Output Enable
Input
When asserted, the COEn signal enables the
ERROROUTn, CO[7:0], DVALIDOUT, BCLKOUT, and
FSTARTOUT signals. Operation of the receiver continues
regardless of the state of the COEn signal.
DVALIDOUT
Valid Data Out
Output
The DVALIDOUT signal indicates that the CO[7:0] signals
contain the corrected channel data. New data is valid on
the CO[7:0] signals when the DVALIDOUT signal is
asserted. DVALIDOUT is not asserted during the
propagated check and GAP bytes. The DVALIDOUT
signal is deasserted after the FEC_RST register bit
(Group 4, APR 55) is set to 1.
ERROROUTn Error Detection Flag
Output
The L64734 asserts the ERROROUTn signal at the
beginning of any frame that contains an uncorrectable
error; it deasserts ERROROUTn at the end of the frame
18
L64733/L64734 Tuner and Satellite Receiver Chipset
if the error condition is removed. The ERROROUTn
signal is exactly aligned with the output data stream; it is
asserted after the FEC_RST register bit is set.
FSTARTOUT Frame Start Output
Output
The L64734 asserts the FSTARTOUT signal during the
first bit of every frame with valid data in Serial Channel
output mode, and during the first byte in Parallel Channel
output mode. FSTARTOUT is valid only when the
DVALIDOUT signal is asserted. The FSTARTOUT signal
is deasserted after the FEC_RST register bit is set.
Microcontroller Interface
The Microcontroller interface connects the L64734 to an external
microcontroller.
INTn
Interrupt
Output
The L64734 asserts INTn when an internal, unmasked
interrupt flag is set. The INTn signal remains asserted as
long as the interrupt condition persists and the interrupt
flag is not masked.
SADR[1:0]
Serial Address
Input
The SADR[1:0] signals are the two programmable bits of
the serial address for the L64734.
SCLK
Serial Clock
Bidirectional
This is the serial clock pin for a two-wire serial protocol.
SDATA
Serial Data
Bidirectional
This is the serial data pin for a two-wire serial protocol.
Synthesizer Control Interface
The Synthesizer Control interface lets the L64734 control the L64733
frequency synthesizer.
FDOUB
Frequency Doubler
Output
When FDOUB is asserted, the frequency doubler on the
L64733 Tuner IC is enabled. When FDOUB is
deasserted, the frequency doubler is disabled. This
output is set by register programming.
L64733/L64734 Tuner and Satellite Receiver Chipset
19
MODn, MODp Modulus Selector
Output
These signals are low-voltage differential signals from the
L64734 modulus selector programmable counter (A). The
signals are clocked by PSOUT. A positive MODp with
respect to MODn selects a divide by 32 at the dual
modulus prescaler on the L64733 Tuner IC. A negative
MODp with respect to MODn selects a divide by 33.
Counter A can be programmed to count down from a
particular value by register bit programming.
PLLINn, PLLINp
PLL Differential Counter M
Output
These signals are low-voltage differential signals from the
L64734 programmable synthesizer counter (M). The
signals are clocked by PSOUT. PLLINp is positive with
respect to PLLINn for one PSOUT cycle. The repetition
rate is 0.5 MHz for a 4 MHz reference crystal. The
counter M can be programmed to count down from a
particular value by register bit programming.
PSOUTn, PSOUTp
Prescaler Output
Output
These signals are differential signals to the L64734 from
the L64733. The programmable counters on the L64734
are clocked on the rising edge of the PSOUT signal.
RESO_LVDS LVDS Buffers Precision Resistor
Output
The RESO_LVDS output must be connected to a resistor
(6.8 kΩ ±5%) that controls the swing of the LVDSOUT
buffers used to drive the differential signals MODp,
MODn, and PLLINp, PLLINn. Connect the other side of
the resistor to ground.
VREF_LVDS
20
LVDS Buffers Reference Voltage
Input
The VREF_LVDS input is a 1.2 V ±10% voltage level that
controls the common mode voltage of the LVDSOUT
buffers used to drive the differential signals MODp,
MODn, and PLLINp, PLLINn.
L64733/L64734 Tuner and Satellite Receiver Chipset
Tuner Control Interface
The Tuner Control interface contains signals that control the L64733
Tuner IC.
FLCLK
Filter Control Clock
Output
FLCLK is the output of a programmable integer value
divider clocked by the demodulator sampling clock,
PCLK. The division ratio can be programmed with
register bits. The frequency of FLCLK multiplied by 16 is
the 3 dB cutoff of the programmable low-pass filters on
the L64733.
INSEL
RF Input Select
Output
When INSEL is asserted, the L64733 tuner selects the
normal mode. When INSEL is deasserted, the L64733
selects the Loop-Through mode.
Typical Operating Circuit
Figure 7 is a diagram of a typical operating circuit for the chipset,
including external components. Not all external components are shown.
See the L64733/34 Evaluation Board User’s Guide for complete
schematic details.
L64733/L64734 Tuner and Satellite Receiver Chipset
21
22
Figure 7
Typical Operating Circuit
28 V
22K
1K
6.8K
Stripline
Inductors (2)
20 20
1K
37
38
39
40
41
42
43
44
45
46
47
48
VCC
0.2 µF
47 pF
180 pF
180 pF
6 MHz
75 Ω
100 pF
75 Ω 100 pF
VCC
CFLT
XTLn
XTLp
GND1
VCC
RFINn
RFINp
GND1
GNDSUB1
QDCn
QDCp
L64733
INSEL
AGC2
AGC1
CPG2
XTLOUT
VCC
CPG1
RFOUT
GND1
GNDSUB1
IDCp
IDCn
0.1 µF
1
2
3
4
5
6
7
8
9
10
11
12
PSOUTp
PSOUTn
VCC
GND1
GND1
TANKn
VRLO
TANKp
VCC
GND1
FB
CP
PLLINn
PLLINp
MODn
MODp
GND1
IOUTp
IOUTn
VCC
QOUTp
QOUTn
FDOUB
FLCLK
36
35
34
33
32
31
30
29
28
27
26
25
47K
AGC Filter
24
23
22
21
20
19
18
17
16
15
14
13
L64733/L64734 Tuner and Satellite Receiver Chipset
100 pF
BC847
0.1 µF
75 Ω
100 pF
ADCVDDI
IVINp
IVINn
ADCVSSI
VREFP
VMID
VREFN
ADCVDDQ
QVINp
QVINn
ADCVSSQ
VDD
VSS
FDOUB
FLCLK
INSEL
AGC2
AGC1
VDD
VSS
XCTR[1]
XCTR[0]
XCTR[2]
XCTR[3]
XCTR_IN
VDD
VSS
IBYPASS[5]
L64734
VSS
VDD
PLLVSS
LP2
PLLAGND
PLLVDD
PCLK
LCLK
VSS
VDD
CO[0]
CO[1]
CO[2]
CO[3]
VSS
VDD
CO[4]
CO[5]
CO[6]
CO[7]
VSS
VDD
BCLKOUT
DVALIDOUT
FSTARTOUT
ERROROUTn
VSS
VDD
COEn
IDDTn
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
1. The ground connections for the L64733 are provided through a metal plate under the IC,
rather than by direct connection of the ground pins to the PCB.
2. Not all external components are shown. Refer to the L64733/34 Evaluation Board
User’s Guide for complete details.
VDD
VSS
XOOUT
XOIN
VSS
CLK
VDD
QBYPASS[0]
QBYPASS[1]
VSS
VDD
QBYPASS[2]
QBYPASS[3]
QBYPASS[4]
QBYPASS[5]
IBYPASS[0]
VSS
VDD
IBYPASS[1]
IBYPASS[2]
IBYPASS[3]
IBYPASS[4]
0.01 µF
Notes:
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
SADR[1]
SADR[0]
VDD
VSS
SDATA
SCLK
INTn
RESET
VDD
VSS
PSOUTn
PSOUTp
VDD
VSS
PLLINn
PLLINp
RESO_LVDS
VREF_LVDS
MODn
MODp
22 nF 10K
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
Varactors (2)
1nF
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
Specifications
This section contains the electrical, timing, and mechanical specifications
for the L64733/34 chipset.
L64733 Electrical Specifications
This section contains the electrical parameters for the L64733. Table 1
lists the absolute maximum values. Exceeding the values listed can
cause damage to the L64733. Table 2 gives the recommended operating
supply voltage and temperature. Table 3 gives the DC characteristics.
Table 4 gives the AC characteristics. Table 5 summarizes the pins.
Table 1
Symbol
VCC
L64733 Absolute Maximum Rating (Referenced to VSS)
Parameter
DC Supply Voltage
Limits1
Units
−0.5 to +7.0
V
1.05
W
–
Continuous power dissipation up to +70 °C
–
Derating above +70 °C
2
mW/°C
–
Operating temperature
0 to +70
°C
–
Junction temperature
+150
°C
–
Storage Temperature
−65 to +165
°C
27.6
°C/watt
+300
°C
Θja
–
Junction to Ambient Thermal
Resistance2
Lead temperature (soldering 10 sec)
1. Note that the ratings in this table are those beyond which permanent device
damage is likely to occur. Do not use these values as the limits for normal
device operation.
2. The junction to ambient thermal resistance is for the ePad TQFP package, for
a four-layer board.
L64733/L64734 Tuner and Satellite Receiver Chipset
23
Table 2
Recommended Operating Conditions
Limits1 Units
Symbol Parameter
VDD
TA
DC Supply Voltage
Operating Ambient Temperature Range (Commercial)
5 ± 5%
V
70
°C
1. For normal device operation, adhere to the limits in this table. Sustained operation of a device at conditions exceeding these values, even if they are within
the absolute maximum rating limits, can result in permanent device damage
or impaired device reliability. Device functionality to stated DC and AC limits
is not guaranteed if recommended operating conditions are exceeded.
Table 3
DC Characteristics of the L647331
Parameter
Condition
Min
Typ
Max
Units
All DC specs met
4.75
5.0
5.25
V
–
190
220
mA
Input Logic Level HIGH
2.4
–
–
V
Input Logic Level LOW
0
–
0.5
V
−15
–
10
µA
FLCLK Input Level LOW
–
–
1.45
V
FLCLK Input Level HIGH
1.85
–
–
V
−1
–
1
µA
1.08
1.2
1.32
V
–
–
−100
mV
Power Supply
Power Supply Voltage
Power Supply Current
Digital Control Inputs - CPG1, CPG2, INSEL, FDOUB
Input Bias Current
Pin at 2.4 V
Slew-Limited Digital Clock Inputs - FLCLK
FLCLK Input
Resistance/Leakage
Current
50 K series resistor between L64734
and FLCLK pin. L64734 generates
normal CMOS levels
Fast Digital Clock Inputs - MODp, MODn, PLLINp, PLLINn
MODp, MODn, PLLINp,
PLLINn Common Mode Input
Range (VCM)
MODp, MODn, PLLINp,
PLLINn Input Voltage LOW
MODp, MODn, or PLLINp, PLLINn
differential swing around VCM. Need
external 100 Ω termination
(Sheet 1 of 3)
24
L64733/L64734 Tuner and Satellite Receiver Chipset
Table 3
DC Characteristics of the L647331 (Cont.)
Parameter
Condition
Min
Typ
Max
Units
MODp, MODn, PLLINp,
PLLINn Input Voltage HIGH
MODp, MODn, or PLLINp, PLLINn
differential swing around VCM. Need
external 100 Ω termination
100
–
–
mV
MODp, MODn, PLLINp,
PLLINn Input Current
MODp, MODn, PLLINp, PLLINn
−5
–
+5
µA
2.16
2.4
2.64
V
Digital Clock Outputs - PSOUTp, PSOUTn
PSOUTp, PSOUTn Common
Mode Output Range (VCM)
PSOUTp, PSOUTn Output
Voltage LOW
PSOUTp, PSOUTn differential swing
around VCM. Driving LSI PECL Load
(±10 µA)
–
−215
−150
mV
PSOUTp, PSOUTn Output
Voltage HIGH
PSOUTp, PSOUTn differential swing
around VCM. Driving LSI PECL Load
(±10 µA)
150
215
–
mV
MOD = HIGH
32
–
32
–
MOD = LOW
33
–
33
–
8
–
8
–
CPG1, CPG2 = 0, 0
0.08
0.1
0.12
mA
CPG1, CPG2 = 0, 1
0.24
0.3
0.36
mA
CPG1, CPG2 = 1, 0
0.48
0.6
0.72
mA
CPG1, CPG2 = 1, 1
1.44
1.8
2.16
mA
CPG1, CPG2 = 0, 0
−0.12
−0.1
−0.08
mA
CPG1, CPG2 = 0, 1
−0.36
−0.3
−0.24
mA
CPG1, CPG2 = 1, 0
−0.72
−0.6
−0.48
mA
CPG1, CPG2 = 1, 1
−2.16
−1.8
−1.44
mA
−25
–
25
nA
−5
–
5
%
Synthesizer
Prescaler Ratio
Reference Divider Ratio
Charge Pump Output HIGH
Current (at FB)
Charge Pump Output LOW
Current (at FB)
Charge Pump Output
Leakage Current
Charge Pump Positive-toNegative Current Matching
FB self-biased
(Sheet 2 of 3)
L64733/L64734 Tuner and Satellite Receiver Chipset
25
Table 3
DC Characteristics of the L647331 (Cont.)
Parameter
Condition
Min
Typ
Max
Units
100
–
–
µA
−50
–
50
µA
1
–
–
VPP
IOUTp, IOUTn, QOUTp,
QOUTn Common
Mode Voltage
0.65
–
0.85
V
IOUTp, IOUTn, QOUTp,
QOUTn DC Offset Voltage
−50
–
50
mV
Charge Pump Output
Transistor Base Current Drive
Analog Control Inputs - AGC1, AGC2
Input Bias Current
1 V < Pin < 4 V
Baseband Outputs - IOUTp, IOUTn, QOUTp, QOUTn
Output Swing
Loaded with 2 K differential across
IOUTp, IOUTn, and QOUTp, QOUTn
(Sheet 3 of 3)
1. For symbol rates below 15 MSymbols/s, the maximum input power might be subject to shifting down
by roughly 10 * log(15/Rs[MSymbols/s]) dB due to channel bandwidth reduction.
26
L64733/L64734 Tuner and Satellite Receiver Chipset
Table 4
AC Characteristics of the L64733
Parameter
Condition
Min
Typ
Max
Units
RFIN Input Frequency
Range
Meets all following AC specs
925
–
2175
MHz
RFIN Single-Carrier
Input Power
RF level needed to produce 0.59 VPP
−65
–
−251
dBm
AGC1 Range
1 V < AGC1 < 4 V
50
–
–
dB
AGC2 Range
1 V < AGC2 < 4 V
19
–
–
dB
RFIN referred IP3
(front-end contributions)
AGC1 gain set for
−25 dBm input level
(0.59 VPP output), and
AGC2 set to maximum
gain (VAGC2 = 1 V). 2
signals at FLO
+ 32 MHz, FLO
+ 72 MHz
–
–
–
3
7
8
–
–
–
dBm
dBm
dBm
Baseband 1 dB
Compression Point
IOUTp, IOUTn, QOUTp, QOUTn have
1 signal within filter BW
2
–
–
VPP
RFIN Referred IP2
PRFIN = −25 dBm, FLO = 951 MHz
–
15.5
–
dBm
Noise Figure
At maximum gain AGC1, AGC2
–
11.5
–
dB
RFIN Worst Case
Return Loss
Complex “75 Ω source” subject to
board, connector parasitics.
–
11
–
dB
LO Leakage Power
at RFIN
950 MHz to 2150 MHz, subject to
board layout
–
−65
–
dBm
Second Harmonic
Rejection
Due to LO-generated 2nd harmonic
27
–
–
dB
Half-Harmonic Rejection
and x 1.5 Harmonic
Rejection1, 2
Due to RFIN-generated 2nd harmonic
–
27
–
dB
–
2.5
1.8
0.8
–
dB
RF Front End
@2175 MHz
@1550 MHz
@925 MHz
Loop Through
Gain
@2175 MHz
@1550 MHz
@925 MHz
(Sheet 1 of 3)
L64733/L64734 Tuner and Satellite Receiver Chipset
27
Table 4
AC Characteristics of the L64733 (Cont.)
Parameter
Condition
Min
Typ
Max
Units
RFIN referred IP3
(when Loop-Through
enabled)
At PRFIN = −25 dBm
–
5
7
9
–
dBm
–
12.0
–
dB
Subject to board and connector
parasitics
–
8
–
dB
IOUTp, IOUTn, QOUTp,
QOUTn Differential
Output Voltage Swing
2 kΩ differential load, IOUTp, IOUTn,
QOUTp, QOUTn. Expect 20 pF from
each pin to GND
1
–
–
VPP
IOUTp, IOUTn, QOUTp,
QOUTn Output
Impedance
Per side, IOUTp, IOUTn, QOUTp,
QOUTn. To 200 MHz
–
–
50
Ωs
Baseband Highpass
−3 dB Point
0.22 µF caps connected from IDCp to
IDCn, and QDCp to QDCn.
–
–
750
Hz
LPF Nominal Cutoff
Frequency Range
Fc is −3 dB point of filter
8
–
33
MHz
–
14.5 ·
FFLCLK + 1
–
–
@2175 MHz
@1550 MHz
@925 MHz
Noise Figure
Worst-Case Return Loss
Baseband
LPF Nominal Fc
Baseband Frequency
Response
Deviation from ideal 7th-order Butterworth, measure to F - 3 dB x 0.7.
Include front-end tilt effects
−0.5
–
0.5
dB
LPF Cutoff Frequency
Accuracy
Measured −3 dB point
−5.5
−10
–
–
5.5
10
%
%
Quadrature Gain Error
Includes effects from baseband filters
–
–
1.2
dB
Quadrature Phase Error
Measure at 125 kHz
–
–
4
Deg
4
–
7.26
MHz
0.8
1.0
1.3
VPP
–
2.0
–
V
@8 MHz
@31.4 MHz
Synthesizer
Crystal Frequency Range
XTLOUT Voltage Levels
XTLOUT DC Level
Measured on 10 pF // 1 MΩ
(Sheet 2 of 3)
28
L64733/L64734 Tuner and Satellite Receiver Chipset
Table 4
AC Characteristics of the L64733 (Cont.)
Parameter
Condition
Min
Typ
Max
Units
MODp, MODn Delay
Must assert MOD level within this time
period to ensure that the next PSOUT
period gives correct count. Delay is
with respect to rising edge of PSOUT
(previous count).
–
–
8.5
ns
PLLINp, PLLINn and
With respect to rising edge of PSOUT.
MODp, MODn Hold Time This means that PSOUT need not
continue to be asserted after MOD has
given correct count.
0
–
–
ns
543
–
1180
MHz
1 kHz offset. Depends on PLL loop
gain.
–
−55
–
dBc/
Hz
10 kHz offset. Depends on PLL loop
gain.
–
−75
–
dBc/
Hz
100 kHz offset
–
−95
–
dBc/
Hz
LO Buffer Frequency
Range when overdriven
by external LO
FDOUB = LOW
925
–
2175
MHz
LO Input Port VSWR
Over Band, when overdriven by external LO
925 MHz < FLO < 2175 MHz. Assume
series resistors to TANKp and TANKn
pins
–
–
2:1
–
Required external LO
Input Power Range
Differential drive into TANKp, TANKn.
50 Ω source.
−15
–
−5
dBm
Local Oscillator
LO Tuning Range
LO Phase Noise, Including Doubler. Subject to
LC tank implementation.
(Sheet 3 of 3)
1. x 1.5 harmonic rejection for FLO = 725 MHz.
2. The L63733 is available with the half-harmonic specification guaranteed to 38 dB typical. Contact your
LSI Logic sales representative for further information.
L64733/L64734 Tuner and Satellite Receiver Chipset
29
Table 5
L64733 Pin Description Summary
Mnemonic
Description
Type
AGC1
Automatic Gain Control 1
Input
AGC2
Automatic Gain Control 2
Input
CFLT
Bias Voltage Bypass
CP
Charge Pump
CPG[2:1]
Charge Pump Gain
FB
Feedback Charge Pump Transistor Drive
FDOUB
Frequency Doubler
Input
FLCLK
Filter Clock
Input
IDCp
I-Channel DC Offset Correction (noninverting)
Input
IDCn
I-Channel DC Offset Correction (inverting)
Input
INSEL
RF Port Input Select
Input
IOUTp
I-Channel Baseband Data (noninverting)
Output
IOUTn
I-Channel Baseband Data (inverting)
Output
MODp
Prescaler Modulus (noninverting)
Input
MODn
Prescaler Modulus (inverting)
Input
PLLINp
Phase Detector (noninverting)
Input
PLLINn
Phase Detector (inverting)
Input
PSOUTp
Prescaler (noninverting)
Output
PSOUTn
Prescaler (inverting)
Output
QDCp
Q-Channel DC Offset Correction (noninverting)
Input
QDCn
Q-Channel DC Offset Correction (inverting)
Input
QOUTp
Q-Channel Baseband Data (noninverting)
Output
QOUTn
Q-Channel Baseband Data (inverting)
Output
RFINp
RF Input (noninverting)
(Sheet 1 of 2)
30
L64733/L64734 Tuner and Satellite Receiver Chipset
Bidirectional
Output
Input
Output
Input
Table 5
L64733 Pin Description Summary (Cont.)
Mnemonic
Description
Type
RFINn
RF Input (inverting)
Input
RFOUT
RF Output (Loop-Through)
TANKp
Oscillator Tank Port (noninverting)
Input
TANKn
Oscillator Tank Port (inverting)
Input
VRLO
Local Oscillator Regulator Bypass
XTLp
Crystal Oscillator Port (noninverting)
Input
XTLn
Crystal Oscillator Port (inverting)
Input
XTLOUT
Crystal Out
Output
Bidirectional
Output
(Sheet 2 of 2)
L64734 Electrical Specifications
This section contains the electrical parameters for the L64734. Table 6
lists the absolute maximum values. Exceeding the values listed can
cause damage to the L64734. Table 7 gives the recommended operating
supply voltage and temperature conditions. Table 8 shows the pin
capacitance. Table 9 gives the DC characteristics. Table 10 summarizes
the pins.
Table 6
L64734 Absolute Maximum Rating (Referenced to VSS)
Symbol Parameter
VDD
DC Supply Voltage
VIN
LVTTL Input Voltage
VIN
5 V Compatible Input Voltage
IIN
DC Input Current
TSTG
Storage Temperature Range (Plastic)
Limits1
Units
−0.3 to +3.9 V
V
−1.0 to VDD +0.3
V
−1.0 to 6.5
V
±10
mA
−40 to +125
°C
1. Note that the ratings in this table are those beyond which permanent device
damage is likely to occur. Do not use these values as the limits for normal
device operation.
L64733/L64734 Tuner and Satellite Receiver Chipset
31
Table 7
L64734 Recommended Operating Conditions
Symbol Parameter
VDD
DC Supply Voltage
Limits1
Units
+3.14 to 3.47
V
0 to +70
°C
TA
Operating Ambient Temperature Range
(Commercial)
Tj
Junction Temperature
+125
°C
Θja
Junction to Ambient Thermal Resistance2
21.7
°C/watt
Θjc
Junction to Case Thermal Resistance3
5
°C/watt
1. For normal device operation, adhere to the limits in this table. Sustained
operation of a device at conditions exceeding these values, even if they are
within the absolute maximum rating limits, can result in permanent device
damage or impaired device reliability. Device functionality to stated DC and
AC limits is not guaranteed if recommended operating conditions are
exceeded.
2. The junction to ambient thermal resistance is for the PQFPt (U4) package,
for a four-layer board.
3. The junction to case thermal resistance is valid only for measurements in an
isothermal environment including the board and package.
Table 8
Symbol
CIN
COUT
L64734 Capacitance
Parameter1
Max
Units
Input Capacitance
5
pF
Output Capacitance
5
pF
1. Measurement conditions are VIN = 3.3 V, TA = 25 ˚C, and
clock frequency = 1 MHz.
32
L64733/L64734 Tuner and Satellite Receiver Chipset
Table 9
DC Characteristics of the L64734
Symbol
Parameter
VDD
Condition1
Min
Typ
Max
Units
Supply Voltage
3.0
3.3
3.6
V
VIL
Input Voltage LOW
VSS
−0.5
–
0.8
V
VIH
Input Voltage HIGH
LVTTL Com/Ind/Mil
Temp Range
2.0
–
VDD
+ 0.3
V
5 V compatible
2.0
–
5.5
V
–
1.4
2.0
V
VT
Switching Threshold
IIL
Input Current Leakage
VDD = Max,
VIN = VDD or VSS
−10
±1
10
µA
IIPU
Input Current Leakage
with Pull-up
VIN = VSS
−62
−215
−384
µA
IIPD
Input Current Leakage
with Pull-down
VIN = VDD
−62
−215
−384
µA
VOH
Output Voltage HIGH
IOH = −1.0, −2.0, −4.0,
−6.0, −8.0, −12.0 mA
2.4
–
VDD
V
VOL
Output Voltage LOW
IOH = 1.0, 2.0, 4.0, 6.0,
8.0, 12.0 mA
–
0.2
0.4
V
IOZ
3-State Output Leakage
Current
VDD = Max,
VOUT = VSS or 3.5 V
−10
±1
10
µA
IDD
Quiescent Supply
Current
VIN = VDD or VSS
2
mA
ICC
Dynamic Supply Current 20 Mbaud, rate = 3/4,
VDD = 3.3 V, Fs =
75 MHz
–
290
–
mA
VCM
Midpoint of PSOUTp,
PSOUTn inputs
–
2.4
–
V
VIH_PECL
Input Voltage HIGH level
(DC)
VCM
+ 50 mV
–
–
V
PSOUTp − PSOUTn =
50 mV
–
(Sheet 1 of 2)
L64733/L64734 Tuner and Satellite Receiver Chipset
33
Table 9
DC Characteristics of the L64734 (Cont.)
Symbol
Parameter
Condition1
VIL_PECL
Input Voltage LOW level
(DC)
PSOUTp − PSOUTn =
50 mV
IIL_PECL
Input LOW current
IIH_PECL
Input HIGH current
Min
Typ
Max
Units
–
–
VCM
−50 mV
V
VIN = VSS
−10
–
–
µA
VIN = VDD
–
–
+10
µA
–
1.2
–
V
VRESO_LVDS Output Voltage on pin
RESO_LVDS
VOH_LVDS
Output Voltage HIGH
level (DC)
On PLLINp/PLLINn,
MODp/MODn signals
1.253
1.373
1.437
V
VOL_LVDS
Output Voltage LOW
level (DC)
On PLLINp/PLLINn,
MODp/MODn signals
1.030
1.032
1.059
V
(Sheet 2 of 2)
1. Specified at VDD = 3.3 V ± 5% at ambient temperature over the specified range.
Table 10
L64734 Pin Description Summary
Mnemonic
Description
Type
ADCVDDI/Q
ADC Power
Input
ADCVSSI/Q
ADC Analog Ground
Input
AGC1, AGC2
Power Control
Outputs
BCLKOUT
Byte Clock Out
Output
CLK
Input Clock
CO[7:0]
Channel Data Out
COEn
Channel Output Enable
DVALIDOUT
Valid Data Out
Output
ERROROUTn
Error Detection Flag
Output
FDOUB
Frequency Doubler
Output
(Sheet 1 of 3)
34
L64733/L64734 Tuner and Satellite Receiver Chipset
Input
Output
Input
Table 10
L64734 Pin Description Summary (Cont.)
Mnemonic
Description
FLCLK
Filter Control Clock
Output
FSTARTOUT
Frame Start Output
Output
IBYPASS[5:0]
I Channel Data (ADC bypassed)
Input
IDDTn
Test
Input
INSEL
RF Input Select
Output
INTn
Interrupt
Output
IVINn, IVINp
I Channel Data
LCLK
Decimated Clock Output
LP2
Input to VCO
MODp, MODn
Modulus Selector
Outputs
PCLK
PLL Clock Output
Output
PLLAGND
PLL Analog Ground
PLLINp, PLLINn
PLL Differential Counter M
PLLVDD
PLL Power
Input
PLLVSS
PLL Ground
Input
PSOUTp, PSOUTn Prescaler Output
Type
Input
Output
Input
Input
Outputs
Outputs
QBYPASS[5:0]
Q Channel Data (ADC bypassed)
Input
QVINn, QVINp
Q Channel Data
Input
RESET
Reset
Input
RESO_LVDS
LVDS Buffers Precision Resistor
SADR[1:0]
Serial Address
SCLK
Serial Clock
Bidirectional
SDATA
Serial Data
Bidirectional
VREF_LVDS
LVDS Buffers Reference Voltage
Output
Input
Input
(Sheet 2 of 3)
L64733/L64734 Tuner and Satellite Receiver Chipset
35
Table 10
L64734 Pin Description Summary (Cont.)
Mnemonic
Description
Type
VREFP
Reference Voltage, Positive
Input/Output
VREFN
Reference Voltage, Negative
Input/Output
VMID
Reference Voltage, Middle
Input/Output
XCTR_IN
Control Input
XCTR[3:0]
Control Output/Sync Status Flag
XOIN
Crystal Oscillator In
XOOUT
Crystal Oscillator Out
Input
Output
Input
Output
(Sheet 3 of 3)
L64734 AC Timing
This section includes AC timing information for the L64734. During AC
testing, HIGH inputs are driven to 3.0 V, and LOW inputs are driven to
0 V. For transitions between HIGH, LOW, and invalid states, timing
measurements are made at 1.5 V, as shown in Figure 8.
Figure 8
AC Test Load and Waveform for Standard Outputs
Test
Point
Output
1.5 V
CL = 15 pF
For 3-state outputs, timing measurements are made from the point at
which the output turns ON or OFF. An output is ON when its voltage is
greater than 2.5 V or less than 0.5 V. An output is OFF when its voltage
is less than VDD − 0.5 V or greater than 0.5 V, as shown in Figure 9.
36
L64733/L64734 Tuner and Satellite Receiver Chipset
Figure 9
Test
Point
AC Test Load and Waveforms for 3-State Outputs
Iref = 20 mA
Output
Vref = 1.5 V
Vref
2.5 V
0.5 V
VDD – 0.5 V
0.5 V
55 pF
Iref = -20 mA
Synchronous timing is shown in Figure 10. Synchronous inputs must
have a setup and hold relationship with respect to the clock signal that
samples them. Synchronous outputs have a delay from the clock edge
that asserts them.
Figure 10
L64734 Synchronous AC Timing
1
2
3
PCLK
BCLKOUT
4
5
INPUTS
6
OUTPUTS
The reset pulse requirements are shown in Figure 11.
Figure 11
L64734 RESET Timing Diagram
7
8
RESET
L64733/L64734 Tuner and Satellite Receiver Chipset
37
Figure 12 shows the relationship of the L64734 3-state signals to the
COEn signal.
Figure 12
L64734 Bus 3-State Delay Timing
COEn
9
9
CO
FSTARTOUT
ERROROUTn
DVALIDOUT
BCLKOUT
Figure 13 shows the relationship of the L64733 PSOUTp and PSOUTn
prescaler signals to the signals fed back to the L64733 from the L64734
to control the synthesizer.
Figure 13
L64734 Synchronous AC Timing - Synthesizer Control
10
11
12
PSOUTn
PSOUTp
13
PLLINp, MODp
PLLINn, MODn
38
L64733/L64734 Tuner and Satellite Receiver Chipset
The numbers in the first column of Table 11 refer to the timing
parameters shown in the preceding figures. All parameters in the timing
tables apply for TA = 0 ˚C to 70 ˚C and a capacitive load of 15 pF.
Table 11
L64734 AC Timing Parameters
Parameter
Description
Min
Max
Units
11.1
33.31
ns
1
tCYCLE
Clock Cycle for PCLK
2
tPWH
Clock Pulse Width HIGH
6
–
ns
3
tPWL
Clock Pulse Width LOW
5
–
ns
4
tS
Input Setup Time to CLK
4
–
ns
5
tH
Input Hold to CLK
4
–
ns
6s tODS
Output Delay from PCLK, serial mode
3
8
ns
6p tODP
Output Delay from BCLKOUT, parallel
mode
3
–
PCLK
cycles
7
tRWH
Reset Pulse Width HIGH
3
–
CLK
cycles
8
tWK
Wake-Up Time
280
–
CLK
cycles
9
tDLY
Delay from COEn
–
6
ns
10
tCYCLE_PS Clock Cycle for PSOUTp, PSOUTn
clock
14
35
ns
11
tPWH_PS
PSOUT Clock Pulse Width HIGH
6
–
ns
12
tPWL_PS
PSOUT Clock Pulse Width LOW
6
–
ns
13
tOD_PS
Output Delay from PSOUT
4
8.5
ns
1. Minimum Fs (sampling clock = 30 MHz).
L64733/L64734 Tuner and Satellite Receiver Chipset
39
L64733/34 Chipset Ordering and Part Marking Information
The L64733 and the L64734 are ordered as a set. Table 12 gives
ordering information for the chipset.
Table 12
L64733/34 Chipset Ordering Information
Order Number
Package Type
Operating Range
L64733B
48-pin TQFP
Commercial
L64734C-45
100-pin PQFPt
Commercial
Table 13 gives part marking information for the two chips.
Table 13
L64733 and L64734 Part Marking Information
Part
Production Chip Marking
L64733 rev. B
LSI 64733
MAX2104
YYWW+ESD
MAXIM
L64734 rev. C
LSI
L64734C-45
DBS Receiver
FMA YYWW+ESD
Assy Lot #
65060A1
OAS515U4FAA
Country of Origin
The tables and figures that follow provide pinouts and mechanical
drawings for each package in the chipset.
40
L64733/L64734 Tuner and Satellite Receiver Chipset
L64733 Pinout and Packaging Information
Pinouts
Figure 14 gives the pinout for the 48-pin TQFP L64733 package.
L64733 48-Pin TQFP Pinout
36
35
34
33
32
31
30
29
28
27
26
25
PLLINn
PLLINp
MODn
MODp
GND
IOUTp
IOUTn
VCC
QOUTp
QOUTn
FDOUB
FLCLK
Figure 14
37
38
39
40
41
42
43
44
45
46
47
48
Top View
24
23
22
21
20
19
18
17
16
15
14
13
INSEL
AGC2
AGC1
CPG2
XTLOUT
VCC
CPG1
RFOUT
GND
GNDSUB
IDCp
IDCn
VCC
CFLT
XTLn
XTLp
GND
VCC
RFINn
RFINp
GND
GNDSUB
QDCn
QDCp
1
2
3
4
5
6
7
8
9
10
11
12
PSOUTp
PSOUTn
VCC
GND
GND
TANKn
VRLO
TANKp
VCC
GND
FB
CP
L64733/L64734 Tuner and Satellite Receiver Chipset
41
Mechanical Drawing
Figure 15 is a mechanical drawing for the 48-pin TQFP L64733 package.
Figure 15
L64733 48-Pin TQFP Mechanical Drawing
BOTTOM VIEW
TOP VIEW
D
D/2
D1
.15 MIN.
D1/2
E1/2
.50 MAX.
EXPOSED PAD
CORNER TAB DETAIL
A
e
E1
E
EVEN LEAD SIDES
E/2
e/2
SEE DETAIL “A”
8 PLACES
A
11–13°
0° MIN.
M
SEE DETAIL “B”
b
WITH LEAD FINISH
A2
A1
DATUM
PLANE
-H0.08 R. MIN.
0–7°
0.20 MIN.
0.09/0.20
0.09/0.16
b
1
BASE METAL
Notes:
1. All dimensioning and tolerancing conform to Ansi Y14.5–1982.
2. Datum plane – H – is located at mold parting line and coincident
with lead, where lead exits plastic body at bottom of parting line.
3. Dimensions D1 and E1 do not include mold protrusion. allowable mold
protrusion is 0.254 mm on D1 and E1 dimensions.
4. The top of package is smaller than the bottom of package by
0.15 millimeters.
5. Dimension B does not include dambar protrusion. Allowable dambar
protrusion shall be 0.08 mm total in excess of the B dimension at
maximum material condition.
6. Controlling dimension: millimeter.
7. Maximum allowable die thickness to be assembled in this package
family is 0.30 millimeters.
8. This outline conforms to Jedec Publication 95 Registration MO–136,
variations AC and AE.
9. Exposed die pad shall be coplanar with bottom of package within
2 mils (0.05 mm).
10. Metal area of exposed die pad shall be within 0.3 mm of the nominal
die pad size.
42
DETAIL “A”
0.08/0.20 R.
0.25
GAUGE PLANE
L
1.00 REF.
DETAIL “B”
S
Y
M
B
O
L
A
A1
A2
D
D1
E
E1
L
M
N
e
b
b1
JEDEC VARIATION
ALL DIMENSIONS IN MILLIMETERS
AE
MIN.
NOM.
0.05
0.95
0.10
1.00
9.00 BSC.
7.00 BSC.
9.00 BSC.
7.00 BSC.
0.60
0.45
0.14
0.17
0.17
L64733/L64734 Tuner and Satellite Receiver Chipset
48
0.5 BSC.
0.22
0.20
MAX.
1.20
0.15
1.05
0.75
0.27
0.23
L64734 Pinout and Packaging Information
Pinouts
Figure 16 gives the pinout for the 100-pin PQFPt L64734 package.
L64734 100-Pin PQFPt Pinout
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
VSS
VDD
PLLVSS
LP2
PLLAGND
PLLVDD
PCLK
LCLK
VSS
VDD
CO[0]
CO[1]
CO[2]
CO[3]
VSS
VDD
CO[4]
CO[5]
CO[6]
CO[7]
VSS
VDD
BCLKOUT
DVALIDOUT
FSTARTOUT
ERROROUTn
VSS
VDD
COEn
IDDTn
Figure 16
Top View
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
XOOUT
XOIN
VSS
CLK
VDD
QBYPASS[0]
QBYPASS[1]
VSS
VDD
QBYPASS[2]
QBYPASS[3]
QBYPASS[4]
QBYPASS[5]
IBYPASS[0]
VSS
VDD
IBYPASS[1]
IBYPASS[2]
IBYPASS[3]
IBYPASS[4]
VDD
VSS
ADCVDDI
IVINp
IVINn
ADCVSSI
VREFP
VMID
VREFN
ADCVDDQ
QVINp
QVINn
ADCVSSQ
VDD
VSS
FDOUB
FLCLK
INSEL
AGC2
AGC1
VDD
VSS
XCTR[1]
XCTR[0]
XCTR[2]
XCTR[3]
XCTR_IN
VDD
VSS
IBYPASS[5]
SADR[1]
SADR[0]
VDD
VSS
SDATA
SCLK
INTn
RESET
VDD
VSS
PSOUTn
PSOUTp
VDD
VSS
PLLINn
PLLINp
RESO_LVDS
VREF_LVDS
MODn
MODp
L64733/L64734 Tuner and Satellite Receiver Chipset
43
Mechanical Drawings
Figure 17 is a mechanical drawing for the 100-pin PQFPt L64734
package.
Figure 17
Important:
44
100-Pin PQFPt (U4) Mechanical Drawing
This drawing might not be the latest version. For board layout and manufacturing, obtain
the most recent engineering drawings from your LSI Logic marketing representative by
requesting the outline drawing for package code U4.
L64733/L64734 Tuner and Satellite Receiver Chipset
Figure 17
Important:
100-Pin PQFPt (U4) Mechanical Drawing (Cont.)
This drawing might not be the latest version. For board layout and manufacturing, obtain
the most recent engineering drawings from your LSI Logic marketing representative by
requesting the outline drawing for package code U4.
L64733/L64734 Tuner and Satellite Receiver Chipset
45
Notes
46
L64733/L64734 Tuner and Satellite Receiver Chipset
Notes
L64733/L64734 Tuner and Satellite Receiver Chipset
47
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Corporate Headquarters
Tel: 408.433.8000
Fax: 408.433.8989
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