TI GC5328

GC5328
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SLWS218A – OCTOBER 2009 – REVISED OCTOBER 2009
GC5328 Low-Power Wideband Digital Predistortion Transmit Processor
Check for Samples: GC5328
FEATURES
1
•
•
•
•
•
•
•
•
Integrated DUC, CFR, and DPD Solution
20-MHz Max. Signal Bandwidth, Based on Max.
DPD Clock of 200 Mhz, Fifth-Order Correction
DUC: Up to 12 CDMA2000/TDSCDMA, 4
W-CDMA, 2–10 MHz or 1–20 MHz OFDMA
Carriers
CFR: Typically Meets 3GPP TS 25.141 < 6.5 dB
PAR, < 8.5 dB PAR for OFDMA Signals
DPD: Short-Term Memory Compensation,
Typical ACLR Improvement > 20 dB
GC5328IZER PBGA Package, 23 mm × 23 mm
1.2-V Core, 1.8-V HSTL, 3.3-V I/O
2.5-W Typical Power Consumption
•
•
TMS320C6727 DPD Optimization Software
Supports Direct Interface to TI High-Speed
Data Converters
APPLICATIONS
•
•
•
•
3 GPP (W-CDMA) Base Stations
3 GPP2 (CDMA2000) Base Stations
WiMAX, WiBRO, and LTE (OFDMA) Base
Stations
Multicarrier Power Amplifiers (MCPAs)
Attenuator
DAC
I/Q
BB Data
GC5328
DAC
I/Q
Modulator
HPA
0–31.5 dB
LPA
LO
DUC-CFR-DPD
Attenuator
ADC
Mixer
Host
Control
Interface
0–31.5 dB
'C6727
DSP
B0278-03
Figure 1. GC5328 System Block Diagram
DESCRIPTION
The GC5328 is a lower-power version of the GC5322 wideband digital predistortion transmit processor. The
GC5328 includes a digital upconverter (DUC) block, a crest factor reduction (CFR) block, a digital predistortion
(DPD) block, feedback (FB) block, and capture buffer (CB) blocks.
The GC5328 GPP block receives the interleaved IQ data from the baseband input. The individual IQ channels
are gain-adjusted in the GPP and routed to the DUC. The GPP and DUC can be bypassed to input a combined
IQ signal. The DUC provides three stages of interpolation and a complex mixer. There are two DUC blocks. The
output from the DUC blocks is combined in the sum chain. Each of the 1 to 12 DUC channels can be summed,
and the composite signal can be scaled.
1
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2009, Texas Instruments Incorporated
GC5328
SLWS218A – OCTOBER 2009 – REVISED OCTOBER 2009
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The CFR block has four serial stages of peak detection and cancellation. The CFR block cancellation filter can
be programmed as real or complex. The CFR peak-reduced output is routed to the Farrow resampler. The
Farrow resampler resamples the CFR output to the DPD clock rate. The Farrow resampler block also has a
complex mixer for composite carrier frequency offset.
The DPD subsystem has a circular limiter, nonlinear DPD correction, and a transmit equalizer. The DPD
correction can reduce the follow-on circuitry distortion products. The DPD output is sent to the BUC. The BUC
provides a post-DPD interpolation, and also provides a complex mixer for frequency offset. The DAC interface
converts the BUC signal output to the interleaved IQ or parallel IQ output signals for the DAC5682Z or DAC5688.
The CB block captures the selected internal reference signal, and the feedback block in two up to 4K capture
buffers. The signal capture can be based on an externally timed event (standard capture buffer), delay after a
timed event, or signal statistics (smart capture buffer). Normally the DPD input and feedback output are selected.
The capture buffers are stored and read by the microprocessor.
The FB block receives the LVDS ADC information and performs signal processing to downconvert the received
signal to 0IF. The FB block also has a feedback-path receive equalizer.
RESETB SYNC SYNC INT UPDATA UPADDR OEB RDB WRB CEB
OUT
16
3
10
GC5328
Pilot
Insertion
Gain
BBin
16
Pilot
Insertion
BBFR
1
AntCal
Insertion
Power
Meter
Medium NarrowBand DUC
Band NarrowBand DUC
Wide DUC NarrowBand DUC
Band
DUC Medium NarrowBand DUC
Band NarrowBand DUC
DUC NarrowBand DUC
MPU Interface
+
Fractional
Resampler
ADC
Interface
Real to Complex
Feedback
Equalizer
To Capture
Buffer
MAGclk
16
DACout
38
Envelope
Interface
DAC
Interface
Bulk Interpolation
+ Mixer
To Capture
Buffer
JTAG
BB
PLL
BBclk
DPD
PLL
DPDclk
Feedback Mixer
and NL Correction
SYNC
2
MAGout
TD
4
CFR
Medium NarrowBand DUC
Band NarrowBand DUC
Wide DUC NarrowBand DUC
Band
DUC Medium NarrowBand DUC
Band NarrowBand DUC
DUC NarrowBand DUC
ADCin
(LVDS)
ADCin 16
(LVDS)
TCK
TRST
TI
TMS
Circular
Limiter
To Capture
Buffer
Transmit
Equalizer
DPD
Capture Buffers
DUCs in
1-Chn Mode
DUCs in
2-Chn Mode
DUCs in
6-Chn Mode
BB Clock Domain
DPD Clock Domain
Active Only in Dual
Antenna Mode
B0279-03
Figure 2. GC5328 Functional Block Diagram
2
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AVAILABLE OPTIONS
TC
–40°C to 85°C
PACKAGED DEVICE
484-Ball PBGA Package, 23 mm × 23 mm
GC5328IZER
REFERENCES
1.
2.
3.
4.
5.
6.
7.
GC532x Architecture Datasheet (NDA, obtain through local TI field application engineer)
GC5328 EVM User Guide, Schematic Diagram (obtain through local TI field application engineer)
GC5325 EVM User Guide, Schematic Diagram TI Web site under GC5325
GC5322 DPD Host Interface Guide (obtain through local TI Field Application Engineer)
GC5328 configuration (obtain through local TI Field Application Engineer)
DSP – TMS320C672x DSP Universal Host Port Interface Reference Guide (SPRU719)
DSP – TMS320C672x DSP External Memory Interface (EMIF) User's Guide (SPRU711)
GC5328 INTRODUCTION
The GC5328 is a flexible transmit sector processor that includes a digital upconverter (DUC) block, a crest factor
reduction (CFR) block, and a digital predistortion (DPD) block and its associated feedback chain. The GC5328
processes composite input bandwidths of up to 20 MHz and processes DPD expansion bandwidths of up to 100
MHz. By reducing both the peak-to-average ratio (PAR) of the input signals using the CFR block and linearizing
the power amplifier (PA) using the DPD block, the GC5328 reduces the costs of multicarrier PAs (MCPA) for
wireless infrastructure applications. The GC5328 applies CFR and DPD while a separate microprocessor (a
Texas Instruments TMS320C6727 DSP) is used to optimize performance levels and maintain target PA
performance levels.
By including the GC5328 in their system architecture, manufacturers of BTS equipment can realize significant
savings on power amplifier bill of materials (BOM) and overall operational costs due to the PA efficiency
improvement. The GC5328 meets multicarrier 3G performance standards (PCDE, composite EVM, and ACLR) at
PAR levels down to 6.5 dB and improves the ACLR, at the PA output, by 20 dB or more. The GC5328 integrates
easily into the transmit signal chain between baseband processors (such as the Texas Instruments
TMS320C64x™ DSP family) and TI high-performance data converters.
A
•
•
•
•
•
•
•
typical GC5328 system application would include the following transmit-chain components:
TMS320C6727B digital signal processor (DSP)
DAC5682 16-bit, 1-Gsps DAC; DAC5688 16-bit, 800-Msps DAC (transmit path)
CDCM7005, CDCE72010 clock generator
TRF3761 integrated VCO/PLL synthesizer
TRF3703 quadrature modulator
ADS6149 14-bit, 250-Msps ADC or ADS5517 11-bit 200-Msps (feedback path)
AMC7823 analog monitoring and control circuit with GPIO and SPI
BASEBAND INTERFACE
The GC5328 baseband interface block accepts baseband signals over an interleaved parallel interface at a data
rate of up to 70 MHz. The input interface supports up to 12 separate baseband carriers. The baseband interface
sends the interleaved IQ data to the DUC, or in DUC bypass to the sum chain, with up to 35-Mhz composite BW.
The baseband interface has 18-bit data (top16) BBData[15.0], BBFrame, and two additional (bottom two data)
MFIO(18,19).
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GC5328
SLWS218A – OCTOBER 2009 – REVISED OCTOBER 2009
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BASEBAND CLOCK (CMOS)
LOW JITTER
GC532x
Customer LOGIC
BBCLK
START_FRAME
TIME
DIVISON
MULTIPLEXED
BASEBAND
DATA
BBCLK
START of MUX-FRAME
BBFR
BBDATA[17:2]
BBDATA[15:0]
BBDATA[1:0]
MFIO[19:18]
TX SYNC
REFERENCE
TX SYNC REFERENCE
TX SYNC 2
REFERENCE
TX SYNC 2 REFERENCE
SYNC A
SYNC B
DGND
SYNC C
B0370-01
Figure 3. Baseband and Sync Interface to GC5328
BASEBAND CLOCK INPUT
The baseband clock input is a CMOS, low-jitter clock.
GAIN/PILOT INSERTION/AntCal INSERTION/POWER METER
Baseband gain can be applied on a per-carrier basis to control the individual channel power accurately through
the system. A UMTS pilot sequence at a programmable gain can be added for antenna calibration. Each
individual baseband channel has an integrated I2 + Q2 power accumulator. The baseband power meters have a
common integration counter and interval counter for all channels. The GPP block has an IPDL detection and
control section to select one of four CFR memories when IPDL autoselection is used. Normally, IPDL 0 is
manually selected.
DIGITAL UPCONVERTERS (DUCs)
The GC5328 DUC block has interpolation filters, programmable delays, and complex mixers for each channel.
There are two DUC blocks within the GC5328. The sum chain after the DUC channel combines the DUC channel
streams or the bypass stream and sends the data to the CFR block. Each DUC can operate in one wide, two
medium, or six CDMA channels. Each DUC has a PFIR for spectral shaping, a CFIR for interpolation and image
rejection, and a bulk interpolation CIC.
The 2 DUCs can support:
• (6 channel/DUC mode) up to 12 – 1.23(8) Mhz CDMA, 1xEVDO, or TDSCDMA carriers
• (2 channel/DUC mode) up to 4 – WCDMA or LTE-5 carriers
• (1 channel/DUC mode) up to 2 – Wibro, Wimax, LTE 10 carriers
• (1 channel/DUC mode) 1 – Wimax or LTE20 carrier
Users can specify the filter characteristics of the DUC. The filters are the programmable finite impulse response
(PFIR), compensating finite impulse response (CFIR), and cascade integrator comb (CIC) filters. Users can also
specify the center frequencies of each carrier with a resolution of 0.25 mHz. Additional controls available in the
DUCs include bulk and fractional-time delay adjustments, phase adjustments, and equalization. The maximum
DUC output bandwidth is 40 MHz.
4
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CREST FACTOR REDUCTION (CFR)
The GC5328 CFR block selectively reduces the peak-to-average ratio (PAR) of wideband digital signals. There
are four peak detection cancellation sections in series in the CFR block. Each stage compares the estimated
peak at the stage input with the target, and subtracts a scaled cancellation peak from the signal. There are 24
cancellers pooled among the four stages. The CFR interpolation filter must have at least 1.6× bandwidth, typical
is 2× BBClock to signal bandwidth.
There are four canceller memories and an update shadow memory that can be used for the auto-IPDL UMTS
select cancellation filter. The shadow memory allows the user to update one of the four filter banks during
operation. The CFR block has a composite RMS meter that can select the CFR input or output for monitoring.
The CFR block for WCDMA reduces TM1, TM3 signals for four adjacent carriers to 6.5 db PAR within the 3GPP
limit. The Wimax 10 reduction for two adjacent carriers is to 8.5 db PAR. TDSCDMA and CDMA performance is
limited by the carrier allocations and carrier coding.The CFR processing complex BW is limited to 62.5% of the
baseband clock rate.
FRACTIONAL FARROW RESAMPLER (FR)
The fractional resampler block takes the peak-reduced composite signals from CFR and resamples this through
fractional interpolation to the DPD processing rate. The user-programmable Farrow resampler supports
upsampling rates from 1× to 64×, with 16-bit precision on the interpolation ratio. After the fractional interpolation,
a complex mixer is available to provide a composite carrier IF offset frequency. A peak I or Q monitor is
provided.
DIGITAL PREDISTORTION (DPD)
The DPD block provides predistortion for up to Nth-order nonlinearities, and can correct multiple orders and
lengths of PA memory effects. The circular hard limiter provides a circular clipper that limits the
magnitude-squared value to –6 dbFS. This is optimized for hardware, and for the allowed gain expansion in the
nonlinear DPD correction.
The DPD has an RMS power meter, and a peak I or Q monitor.
The predistortion is performed for the nonlinear correction in the DPD section. The linear correction is performed
in the Tx equalizer. The predistortion correction terms are computed by an external processor (TMS320C6727
DSP) based on capture buffer information and the DPD software.
The DSP sets up the condition for collecting capture buffer data, retrieves the captured data over the EMIF bus,
and then performs calculations to compute the error and corrections to be used for the transmit path.
The host interface controls the mode of operation of the software in the TI DSP. TI provides a base delivery of
'C6727 software to GC5328 customers that achieves a typical ACLR improvement of 20 dB or more when
compared to a PA without DPD.
DPD CLOCK INPUT
The DPD clock input is an LVDS, low-jitter clock.
BULK UPCONVERTER (BUC)
The bulk upconverter block can interpolate the DPD block output by 1×, 1.5×, 2×, or 3× with a complex output.
The BUC interpolation blocks of 2 and 1.5 can provide 1×, 2×, or 3× interpolation for complex signals. The 1.5×
interpolation after DPD is performed by interpolating by 3 in the BUC and decimating by 2 in the OFMT block.
The BUC mixer can translate the composite IQ predistorted Tx output if the BUC Interpolation is > 1. Note: the
BUC interpolation of 1, 1.5, or 2 is recommended.
OUTPUT FORMATTER AND DAC INTERFACE (OFMT)
The output format and DAC interface presents the GC5328 output in the proper format for the different output
interfaces. The output formatter supports a test pattern for testing the DAC5682Z interface. The two output
interfaces supported for the GC5328 are:
• DAC5682 interleaved IQ
• DAC5688 parallel IQ or interleaved IQ
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GC5328
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GC532x
DAC5682Z
DPD Clock
DAC Clock
CLKIN, CLKINC
ExtTerm
(1)
DataClock
TX21, TX20
DCLK, DCLKC
ExtPullup
(2)
Differential Data
TX[]
(See HW Data Sheet)
D[15:0]P, D[15:0]N
ExtPullup/
PullDown
SYNCP, SYNCN
B0371-01
(1)
ExtTerm – see DAC data sheet.
(2)
ExtPullup, 500 Ω to 1.8 V, only required when DAC Data Clock > 337 MHz
Figure 4. GC5328 to DAC5682Z Interface
DAC5688
GC532x
DPD Clock
DAC Clock
CLKIN, CLKINC
ExtTerm
(1)
DataClock
TX21, TX20
DCLK, DCLKC
ExtTerm1
TX[] - DACI[]
(See HW Data Sheet)
Single-Ended
1.8-V CMOS
DACA[15:0]
ExtTerm1
TX[] - DACQ[]
(See HW Data Sheet)
(2)
Single-Ended
1.8-V CMOS
DACB[15:0]
ExtTerm1
TX18
(2)
(2)
Single-Ended
1.8-V CMOS
TXENABLE
B0372-01
(1)
ExtTerm – see DAC data sheet.
(2)
ExtTerm1 – tester uses 50 Ω to 0.9 V for termination.
Figure 5. GC5328 to DAC5688 Interface
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FEEDBACK PATH (FB)
The feedback path has two LVDS input ports. The A port is preferred (it has better timing). The external ADC
Input is converted or processed to generate a complex signal. The feedback equalizer has eight complex taps as
a receive equalizer. The feedback path has a mixer to translate the complex IF to the 0IF reference. The ADC
feedback rate is at the same rate as the DPD clock (fS). The typical feedback is fS/4, fS3/4 (m), or fS5/4 IF. The
feedback equalizer can provide (m) inverted spectral output, if needed.
The FB complex mixer translates the frequency of the complex input signal to 0IF. The feedback path has the
capability for nonlinear correction with a lookup table. TI ADCs that connect to the feedback path are the SDR
type ADS5444, DDR type ADS5445 (6149, 5517), DDR with reversed data phase ADSC217. The ADC feedback
path has modified connections for shared feedback path operation (see GC5325 schematic, User's Guide, in
References ). The GC5328 simplifies timing by providing a FIFO for each ADC port.
NOTE
There are eight LVDS data lanes and 1 LVDS clock lane. If the ADC has < 8 LVDS
data lanes the MSB of the ADC is connected to LVDS lane 7 (MSB) of the A feedback
port.
ADC
GC532x
MSB ALigned
ADC DDR Data
ADC[7P, 7N, 0P, 0N]
FB[17:2]
(See HW Data Sheet)
DDR Clock
FB[1:0]
ADC_OutClkP, N
B0373-01
Figure 6. LVDS DDR ADC to GC5328 FB Interface
MICROPROCESSOR (MPU) INTERFACE
The MPU interface is designed to interface with external memory interface (EMIF) ports on TI DSPs operating in
asynchronous mode. It consists of a 16-bit bidirectional data bus, a 10-bit address bus, and RDB, WRB, OEB,
and CEB control signals. The CEB and OEB signals to the GC5328 require additional logic outside the
TMS320C6727B; see Table 1.
Table 1. EMIF to GC5328 Microprocessor Interface
6727 DSP EMIF
GC5328
NOTES
EM_D[15.0]
UPDATA[15.0]
EM_A[8.0]
UPADDR[9.1]
EM_BA[1]
UPADDR[0]
EM_CS2
CEB
Note: DSP HD[22.20] are used for logic for multiple chip-select, inverted outputs.
EM_RWB
OEB
Invert RWB send to OEB
EM_WEB
WRB
EM_OEB
RDB
AXRO[7]
Interrupt
Note: DSP [HD22.20] can also be used with a multiplexer to select GC5328 interrupt.
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GC5328
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HOST UHPI
INTERFACE
www.ti.com
Note: One DSP is
shared With
GC532xs
Multiplex
Address
Half Data
UHPI
DSP RST
BOOTMODE
EMIF Addr
Cntl SDRAM
EMIF Data
SDRAM
r
e
s
TI6727
DSP
UPDATA[]
EMIF Addr
Cntl GC5322
DSP JTAG
Inv
RDB, CS2[]
INTROUT
To/From
Other GC5322
UPADDRESS[]
and CNTL CS2-2
First GC532x
INTROUT(2)
UPDATA[]
GPIO
Ant
SelCode
CS2-1
INTROUT
INTROUT
UPADDRESS[]
and CNTL
B0374-01
Figure 7. 6727 DSP to GC5328 EMIF Interface
CAPTURE BUFFERS (SCB)
The GC5328 has two capture buffers of 4096 complex words. The capture buffers are normally used to capture
the Tx reference signal and the feedback output signal. Capture buffer A can capture:
• The TX reference from the DPD after the circular hard limiter
• The feedback output; this represents the waveform as seen by the PA.
• The error output
• Testbus(31:16)
• QRD error output
Capture buffer B can capture:
• The TX reference from the DPD after the circular hard limiter
• The feedback output; this represents the waveform as seen by the PA.
• The error output
• Testbus(15:0)
Standard capture mode – The capture buffers can be armed to collect the 4K complex samples after a
programmable delay following a sync event.
Smart capture mode – There are two trigger conditions that combine the number of samples greater than a
threshold; these are used to find a number of peak events while the transmit signal is above a threshold. In this
case, the magnitude and magnitude-squared of the signal are compared against a threshold and counted. If the
capture buffer finds the trigger condition, the capture logic captures the programmed capture-buffer depth after
the trigger. This is a combination of DSP software and the GC5328 hardware.
NOTE
Capture buffer A has a special mode to source data for diagnostic testing.
The DSP host-interface software has a function to select and get capture-buffer data.
The complex data is then passed from the GC5328 to the EMIF bus, to the DSP, and
back to the host processor.
The DSP host software has a signal-power monitoring function. This uses the
capture-buffer data to perform special monitoring, power measurement, and error
measurements.
8
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There are special DSP software PA protection modes that use the capture buffer to
determine the DPD correction applied to the signal, the error between the DPD
reference input and the feedback signal. The capture buffers are also used in the
initial bulk delay and fractional delay alignment.
INPUT SYNCS AND OUTPUT SYNC
The GC5328 features multiple user-programmable input syncs. There are three syncs sampled with the BBClock,
(A, B, and C), and the Sync D,DC as an LVDS sync sampled by the DPD clock. Internally, the GC5328 can also
generate timed and software-controlled syncs. The sync A input is required for the GC5328 hardware to initialize.
It should ideally be the start of the frame or frame downlink. The output sync is a test signal used for debugging.
The input syncs can be used to trigger:
• Power measurements
• DUC channel delay, dither, and mixer-phase alignment
• Initializing/loading the DUC, feedback, equalizer, LUTs, etc.
• Feedback path tuner alignment
• Capturing and sourcing of data through SCBs
NOTE
The sync A external synchronization should match the customer Tx frame (total Tx
period – i.e., 5 ms).
See the baseband interface figure, these synchronization signals must meet the
timing of the BBClk.
POWER METERS AND PEAK I–or–Q MONITORS
There are three integrated I2 + Q2 power meters in the GC5328:
• GPP – each baseband input channel
• CFR – the CFR input or output, and which antenna stream (0, 1)
• DPD – the input to the DPD nonlinear correction after the DPDL gain, and which antenna stream (0, 1)
There are several peak I or Q monitors within the GC5328.
• FRW– The resampled combined IQ interleaved input to the DPD
• DPD – The input to the DPD nonlinear correction after the DPDL gain
• DPD – After the nonlinear correction in DPD, and separately after the linear correction in DPD
• FDBK – There is a peak monitor at the output of the feedback path.
NOTE
The DSP host software has a HW POWER meter setup and Get(Monitor) function to
configure and get data from the integrated I2+Q2 values.
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PIN ASSIGNMENT AND DESCRIPTIONS
ZER Package
(Top View)
A
B
C
D
E
22
VSS
VSS
VSS
VSS
VSS
21
VSS
VSS
VSS
VSS
20
BB0
BB1
BB2
19
BB3
BB4
18
BB7
17
G
F
J
U
Y
AA
AB
UP
UP
UP
UP
UP
VPP1
VSS1
DATA3 DATA6
DATA9 DATA12 DATA15
VSS
VSS
VSS
VSS
UP
UP
UP
UP
VPP1
DATA4
DATA7 DATA10 DATA13
UP
DATA2
VDD
SHV
UP
DATA5
VDD
SHV
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD1
VDD
VDD
SHV
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
SHV
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VDD
SHV
VDD
VSS
VSS
VSS
VSS
VSS
K
L
M
UP
UP
UP
UP
ADDR ADDR ADDR ADDR
RDB
UP
DATA0
VSS
VSS
UP
UP
UP
ADDR ADDR ADDR
WRB
CEB
UP
DATA1
VSS
VSS
UP
UP
UP
ADDR ADDR ADDR
VDD
SHV
OEB
BB5
BB6
VDD
SHV
VDD
VDD
VDD
VDD
BB8
BB9
BB10
VDD
VDD
VDD
VDD
BB11
BB12
BB13
BB14
VDD
VDD
VDD
SHV
16
BB15
BBFR
BBCLK
VDD
VDD
VDD
15
SYNC SYNC SYNC SYNC
OUT
A
C
B
VDD
SHV
14
VSSA1 VDDA1 VDD
VSS
H
N
P
R
T
V
W
VSS
VSS
VSS
VSS
TEST
MODE
VSS
MVV
DD2
MVV
SS2
INTERRUPT
TDO
VDD
VDD
SHV
VDD
VDD
TDI
TCK
VDD
VDD
VDD
VSS
VDD
SHV
TRSTB
TMS
VDD
VDD
SHV
VDD
VDD
TX37
TX36
TX35
TX34
VDD
VDD
VDD
VDD
VDD
TX33
TX32
TX31
TX30
VSS
VSS
VSS
VSS
VHST
LHV
VDD
TX29
TX28
TX27
TX26
VSS
VSS
VSS
VSS
VSS
VHST
LHV
VDD
TX25
TX24
TX23
TX22
DAC
DAC
REFN REFP
TX21
TX20
UP
UP
UP
DATA8 DATA11 DATA14
13
FB34
FB35
FB32
FB33
VDD
SHV
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VHST
LHV
VDD
12
FB30
FB31
FB28
FB29
VDD
SHV
VDD
VSS
VSS
VSS
VSS
VSS1
VSS
VSS
VSS
VSS
VSS
VHST
LHV
VDD
VSS
VSS
TX19
TX18
11
FB27
FB26
VDD
VDD
VDD
SHV1
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VHST
LHV
VDD
TX14
TX15
TX16
TX17
10
FB25
FB24
FB23
FB22
VDD
SHV
VDD
VSS
VSS1
VSS1
VSS1
VSS1
VSS1
VSS1
VSS1
VSS1
VSS
VHST
LHV
VDD
TX10
TX11
TX12
TX13
9
FB21
FB20
FB19
FB18
VDD
SHV
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VHST
LHV
VDD
TX6
TX7
TX8
TX9
8
FB17
FB16
ADC
IREF
ADC
VREF
VDD
SHV
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VHST
LHV
VDD
TX2
TX3
TX4
TX5
7
FB15
FB14
FB13
FB12
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDDA
TX0
TX1
6
FB11
F10
VDD
VDD
VDD
VDD
VDD
SHV
VDD
VDD
VDD
VDD
SHV
VDD
VDD
VDD
VDD
VDD
SHV
VDD
VDD
VSS
VSS
VDD
SHV
VSSA
5
FB9
FB8
FB7
FB6
VDD
VDD
VDD
VDD
VDD
VDD
VDD
SHV
VDD
VDD
VDD
VDD
VDD
VDD
VDD
DPD
CLK
DPD SYNC SYNC
DC
CLKC
D
4
FB4
FB5
FB2
FB3
VDD
SHV
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
SHV
DPD
IREF
DPD
VREF
VSS
3
FB0
FB1
MFIO
0
MFIO
1
VSS
VPP
MFIO
5
VDD
SHV
MFIO
10
MFIO
13
VDD
SHV
MFIO
18
MFIO
21
MFIO
24
VDD
SHV
MFIO
29
MFIO
32
VSS
RESET
B
VSS
VSS
VSS
2
VSS
VSS
VSS
VSS
VSS
MFIO
3
MFIO
4
MFIO
7
MFIO
9
MFIO
12
MFIO
15
MFIO
17
MFIO
20
MFIO
23
MFIO
26
MFIO
28
MFIO
31
VSS
VSS
VSS
VSS
VSS
1
VSS
VSS
VSS
VSS
VSS
MFIO
2
VPP
MFIO
6
MFIO
8
MFIO
11
MFIO
14
MFIO
16
MFIO
19
MFIO
22
MFIO
25
MFIO
27
MFIO
30
MFIO
33
VSS
VSS
VSS
VSS
= Baseband Input
= Signal Interface
= Power and Biasing
= Microprocessor Interface
= Miscellaneous
= JTAG Interface
P0107-01
10
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PIN FUNCTIONS
PIN
NAME
I/O
NO.
DESCRIPTION
MICROPROCESSOR INTERFACE
OEB
K20
I
Output enable(inv)
CEB
K21
I
Chip enable(inv)
RDB
K22
I
Read strobe (inv)
WRB
J21
I
Write strobe(inv)
UPADDR[9:0]
J22 ,H20, H21, H22, G20, G21, G22, F20, F21, F22
I
Microprocessor address
UPDATA[15:10]
V22, U20, U21, U22, T20, T21
I/O
Microprocessor data
UPDATA[9:0]
T22, R20, R21, P22, N20, N21, N22, L20, L21, L22
I/O
Microprocessor data
INTERRUPT
AA20
O
Microprocessor interrupt
POWER AND BIASING
VDD
Y19, W19, W7, V18, V17, V16, V15, V14, V13, V12,
V11, V10, V9, V8, V7, V6, V5, V4, U19, U18, U17, U16,
U7, U6, U5, U4, T19, T18, T16, T7, T5, T4, R19, R18,
R17, R16, R7, R6, R5, R4, P19, P18, P17, P16, P7, P6,
P5, P4, N19, N18, N17, N16, N7, N6, N5, N4, M19, M18,
M17, M16,M7, M6, M5, M4, L19, L16, L7, L4, K19, K18,
K17, K16, K7, K6, K5, K4, J19, J18, J17, J16, J7, J6, J5,
J4, H19, H18, H17, H16, H7, H6, H5, H4, G19, G18,
G16, G7, G5, G4, F19, F18, F17, F16, F15, F14, F13,
F12, F11, F10, F9, F8, F7, F6, F5, F4, E18, E17, E16,
E7, E6, E5, D16, D11, D6, C14, C11, C6
PWR
1.2-V supply
VSS
AB22, AB4, AB3, AB2, AB1, AA22, AA21, AA3, AA2,
AA1, Y22, Y21, Y12, Y6, Y3, Y2, Y1, W22, W21, W18,
W12, W6, W2, W1, V21, V20, V3, V2, T15, T14, T13,
T12, T11, T10, T9, T8, R15, R14, R13, R12, R11, R10,
R9, R8, P15, P14, P13, P12, P11, P10, P9, P8, N15,
N14, N13, N12, N11, N10, N9, N8, M22, M21, M15,
M14, M13, M12, M11, M10, M9, M8, L15, L14, L13, L12,
L11, L10, L9, L8, K15, K14, K13, K12, K11, K10, K9, K8,
J15, J14, J13, J12, J11, J10, J9, J8, H15, H14, H13,
H12, H11, H10, H9, H8, G15, G14, G13, G12, G11,
G10, G9, G8, E22, E21, E20, E3, E2, E1, D22, D21,
D20, D14, D2, D1, C22, C21, C2, C1, B22, B21, B2, B1,
A22, A21, A2, A1
PWR
Ground
MVDD2
W20
1.2-V monitor, no connect
MVSS2
Y20
GND monitor, no connect
VHSTLHV
U15, U14, U13, U12, U11, U10, U9, U8
PWR
1.8-V supply
VDDSHV
AA6, Y18, W4, V19, T17, T6, R3, P20, M20, L18, L17,
L6, L5, L3, J20, H3, G17, G6, E19, E15, E14, E13, E12,
E11, E10, E9, E8, E4
PWR
3.3-V supply
VDDA
Y7
PWR
1.2-V supply (requires filtering)
VSSA
AB6
PWR
Ground (requires filtering)
VDDA1
B14
PWR
1.2-V supply (requires filtering)
VSSA1
A14
PWR
Ground (requires filtering)
VPP
G1, F3
PWR
1.2-V supply
VPP1
R22, P21
PWR
1.2-V supply
DPDIREF
Y4
PWR
DPD bias, 1 kΩ to VSS
DPDVREF
AA4
PWR
DPD bias to VDD
DACREFP
Y13
PWR
DAC bias, 50 Ω to VSS
DACREFN
W13
PWR
DAC bias, 50 Ω to VDDS
ADCIREF
C8
PWR
ADC bias, 1 kΩ to VSS
ADCVREF
D8
PWR
ADC bias to VDD
BASEBAND INPUT
BB[15:10]
A16, D17, C17, B17, A17, D18
I
Baseband input signal
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PIN FUNCTIONS (continued)
PIN
NAME
I/O
NO.
DESCRIPTION
BB[9:0]
C18, B18, A18, D19, C19, B19, A19, C20, B20, A20
I
Baseband input signal
BBCLK
C16
I
Baseband input clock
BBFR
B16
I
Baseband frame for sample and channel timing
RESETB
W3
I
Chip reset (active-low)
TESTMODE
AB21
I
Tie to GND
SYNCA
C15
I
Programmable general-purpose sync
SYNCB
B15
I
Programmable general-purpose sync
SYNCC
A15
I
Programmable general-purpose sync
SYNCD
AA5
I
DPD-purpose sync
SYNCDC
AB5
I
Complementary DPD-purpose sync
SYNCOUT
D15
O
Programmable general-purpose output sync
DPDCLK
W5
I
Clock to DPD
DPDCLKC
Y5
I
Complementary clock to DPD
TCK
AB19
I
JTAG clock
TDI
AA19
I
JTAG data in
TDO
AB20
O
JTAG data out
TRSTB
AA18
I
JTAG reset (active-low)
TMS
AB18
I
JTAG mode select
MISCELLANEOUS
JTAG INTERFACE
SIGNAL INTERFACE (Tx-DAC, FB-ADC, see next section for Data Converter Connections)
TX[37:30]
W17, Y17, AA17, AB17, W16, Y16, AA16, AB16
O
Transmit to DAC(s)
TX[29:20]
W15, Y15, AA15, AB15, W14, Y14, AA14, AB14, AA13,
AB13
O
Transmit to DAC(s)
TX[19:10]
AA12, AB12, AB11, AA11, Y11, W11, AB10, AA10, Y10,
W10
O
Transmit to DAC(s)
TX[9:0]
AB9, AA9, Y9, W9, AB8, AA8, Y8, W8, AB7, AA7
O
Transmit to DAC(s)
FB[35:30]
B13, A13, D13, C13, B12, A12
I
Feedback from ADC(s)
FB[29:20]
D12, C12, A11, B11, A10, B10, C10, D10, A9, B9
I
Feedback from ADC(s)
FB[19:10]
C9, D9, A8, B8, A7, B7, C7, D7, A6, B6
I
Feedback from ADC(s)
FB[9:0]
A5, B5, C5, D5, B4, A4, D4, C4, B3, A3
I
Feedback from ADC(s)
MFIO[33:0]
V1, U3, U2, U1
I/O
Multifunction input-output interface
MFIO[29:20]
T3, T2 T1, R2, R1, P3, P2, P1, N3, N2
I/O
Multifunction input-output interface
MFIO[19:10]
N1, M3, M2, M1, L2, L1, K3, K2, K1, J3
I/O
Multifunction input-output interface
MFIO[9:0]
J2, J1, H2, H1, G3, G2, F2, F1, D3, C3
I/O
Multifunction input-output interface
SPECIAL POWER-SUPPLY REQUIREMENTS FOR VDDA1, VSSA1, VDDA2, VSSA2
The two PLLs require an analog supply. Each pair (VDDA1, VSSA1) requires a separate filter. These can be
generated by filtering the core digital supply (VDD). A representative filter is shown in Figure 8. The filters should
be located as close as reasonable to their respective pins (especially the bypass capacitors). The ferrite beads
should be series 50R (similar to Murata P/N: BLM31P500SPT; description: IND FB BLM31P500SPT 50R 1206).
In particular, supply VDDA1 must be less than or equal to VDD1 when VDD1 is at the low end of the required
range. The series resistor assures this condition is met.
12
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10 W
VDD1
VDDA or VDDA1
0.01 mF
1 mF
10 W
VSS1
VSSA or VSSA1
S0315-02
Figure 8. Recommended Filter for VDDA, VDDA1 Power
TX OUTPUT TO DAC5682Z AND DAC5688
The earlier figures show the GC5328 to DAC data, sync, and clock signals. These tables list the specific GC5328
to DAC TX connections.
Table 2. GC5328 TX (Single-Channel Single-Ended HSTL – DAC5688)
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
DACI[15:10]
TX15, TX14, TX11, TX10, TX7, TX6
O
DAC-I output
DACI[9:0]
TX3, TX2, TX1, TX0, TX4, TX5, TX8, TX9, TX12,
TX13
O
DAC-I output
DACQ[15:10]
TX24, TX25, TX28, TX29, TX32, TX33
O
DAC-Q output
DACQ[9:0]
TX36, TX37, TX35, TX34, TX31, TX30, TX27,
TX26, TX23, TX22
O
DAC-Q output
DACCLK
TX21
O
Clock to DAC
DACCLKC
TX20
O
Cmplementary clock to DAC
DACSYNC
TX18
O
Output data sync
Table 3. GC5328 TX (Single Channel Differential HSTL – DAC5682Z)
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
DAC[15:10]P
TX10, TX6, TX2, TX0, TX4, TX8
O
DAC positive output
DAC[9:0]N
TX12, TX16, TX23, TX27, TX31, TX35, TX32,
TX36, TX29, TX25
O
DAC negative output
DAC[15:10]N
TX11, TX7, TX3, TX1, TX5, TX9,
O
DAC negative output
DAC[9:0]N
TX13, TX17, TX22, TX26, TX30, TX34, TX33,
TX37, TX28, TX24
O
DAC negative output
DACCLK
TX21
O
Clock to DAC
DACCLKC
TX20
O
Complementary clock to DAC
DACSYNCP
TX14
O
Positive output data sync
DACSYNCN
TX15
O
Negative output data sync
FB INPUT FROM LVDS ADC
Figure 6 shows the ADC data and clock signals to the GC5328. These tables list the specific ADC-to-GC5328 FB
connections. There are two feedback (FB) ports, A and B. Port A has faster timing and is preferred. There are
several ADC styles:
• LVDS DDR – ADS5545 (ADS61x9, ADS5517)
• LVDS DDR – ADS62C17 – reversed data alignment (same connections as ADS5545)
• LVDS SDR – ADS5544
ADCs are typically connected to the GC5328 so the MSB of the ADC is connected to FB port A MSB. The lower
bit numbers follow until the ADC bits are all connected. Any remaining lower-order bits on the FB port should be
terminated with resistors, P connection to GND, N connection to 1.8 V as a logic 0. See the GC5325 schematic
listed under References for an example.
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NOTE
There are special connections for shared-feedback ADCs between GC5328s. See the
GC5325 schematic diagram for the shared feedback connection to (2) GC5328.
Table 4. Single LVDS SDR ADC to FB Ports A and B
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
ADC[15:10]P
FB2, FB4, FB6, FB8, FB10, FB12
I
ADC positive feedback from PA output
DAC[9:0]P
FB14, FB16, FB20, FB22, FB24, FB26, FB28, FB30,
FB32, FB34
I
ADC negative feedback from PA output
ADC[15:10]N
FB3, FB5, FB7, FB9, FB11, FB13
I
ADC negative feedback from PA output
ADC[9:0]N
FB15, FB17, FB21, FB23, FB25, FB27, FB29, FB31,
FB33, FB35
I
ADC negative feedback from PA output
ADCCLK
FB0
I
Clock from ADC
ADCCLKC
FB1
I
Complementary clock from ADC
Table 5. Single LVDS DDR ADC to FB Port A (Preferred)
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
ADCA[7:0]P
FB2, FB4, FB6, FB8, FB10, FB12, FB14, FB16
I
ADC-A positive feedback from PA output
ADC[9:0]P
FB3, FB5, FB7, FB9, FB11, FB13, FB15, FB17
I
ADC-A negative feedback from PA output
ADCACLK
FB0
I
Clock from ADC-A
ADCACLKC
FB1
I
Complementary clock from ADC-A
Table 6. Single LVDS DDR ADC to FB Port B
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
ADCB[7:0]P
FB20, FB22, FB24, FB26, FB28, FB30, FB32, FB34
I
ADC-B positive feedback from PA output
ADCB[7:0]N
FB21, FB23, FB25, FB27, FB29, FB31, FB33, FB35
I
ADC-B negative feedback from PA output
ADCBCLK
FB18
I
Clock from ADC-B
ADCBCLKC
FB19
I
Complementary clock from ADC-B
MPU INTERFACE GUIDELINES
The following section describes the hardware interface between the recommended microprocessor, external
memory, and the GC5328. Users may select a microprocessor that meets their specific system requirements.
Although the hardware can support multiple options, the recommended TMS320C6727 DSP is also fully
supported with host control and adaptation software. Figure 7 and Figure 9 illustrate the hardware interface
between the DSP, GC5328, and SDRAM. The external memory is required to accommodate the computational
efforts of the adaptation algorithm. Although the system evaluation kit suggests dual-parallel 64-Mb/PC133
(128-Mb) memory modules provided by Samsung (K4S641632H-TC(L)75), other memory alternatives are
available.
The use of an external inverter with minimal propagation delay is required for OEB of the GC5328; this device is
necessary when using a TMS320C6727 DSP. Additional documentation for the hardware interface is available in
the TMS320C672x Hardware Designer’s Resource Guide application report (SPRAA87) and TMS320C672x DSP
External Memory Interface (EMIF) user's guide (SPRU711).
14
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HOST UHPI
INTERFACE
Note: One DSP is
shared With
GC532xs
Multiplex
Address
Half Data
UHPI
EMIF Addr
Cntl SDRAM
EMIF Data
DSP RST
BOOTMODE
SDRAM
r
e
s
TI6727
DSP
UPDATA[]
EMIF Addr
Cntl GC5322
DSP JTAG
Inv
RDB, CS2[]
INTROUT
To/From
Other GC5322
UPADDRESS[]
and CNTL CS2-2
First GC532x
INTROUT(2)
UPDATA[]
GPIO
Ant
SelCode
CS2-1
INTROUT
INTROUT
UPADDRESS[]
and CNTL
B0374-01
Figure 9. DSP-to-GC5328 EMIF Interface Specifications
ABSOLUTE MAXIMUM RATINGS
VDD, VDDA
Core supply voltage
VDDS
Digital supply voltage for TX
VDDSHV
Digital supply voltage
VIN
Input voltage (under/overshoot)
Tstg
UNIT
–0.3 to 1.32
V
–0.3 to 2
V
–0.3 to 3.6
V
–0.5 to VDDSHV + 0.5
V
Clamp current for an input/output
–20 to 20
mA
Storage temperature
–65 to 150
°C
300
°C
1
week
Lead soldering temperature, 10 seconds
ESD classification Class 2
(Required 2-kV HBM, 500-V CDM)
(Passed 2.5-kV HBM, 500-V CDM, 200-V MM)
Moisture sensitivity Class 3 (floor life at 30°C/60% H)
Latchup
VALUE
Reflow conditions JEDEC standard
260
°C
JEDEC Level 2 per JEDEC 78 standard (at 90°C and 1.5 × Vmax)
±100
mA
RECOMMENDED OPERATING CONDITIONS
over operating free-air temperature range (unless otherwise noted)
VDD, VDDA2, VPP
Core supply voltages. Note VDDA2 ≤ VDD
TYP
MAX
UNIT
1.2
1.26
V
VDDA1
Analog supply for DPD PLL
1
1.1
VDD
V
VDDS
Digital supply voltage for TX
1.71
1.8
1.89
V
VDDSHV
Digital supply voltage
3.15
3.3
3.45
V
IDD, IDDA1, IDDA2,
IPP
Combined supply current for Vdd, Vdda1, Vdda2, and VPP
3
A
IDDS
Digital supply current for TX
0.25
A
IDDSHV
Digital supply current
0.3
A
85
°C
TC
(1)
(2)
Case temperature
See
(1)
MIN
1.14
See
(2)
–40
30
VDDA1 must be less than VDD1 when VDD1 is low. See recommended filtering circuit in Figure 1 Figure 1. Maximum observed current
on VDDA1 is 8 mA.
Chip specifications in are production tested to 90°C case temperature. QA tests are performed at 85°C.
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RECOMMENDED OPERATING CONDITIONS (continued)
over operating free-air temperature range (unless otherwise noted)
MIN
TJ
(3)
TYP
See (3)
Junction temperature
MAX
UNIT
105
°C
Thermal management may be required for full-rate operation. Sustained operation at elevated temperatures reduces long-term reliability.
Lifetime calculations based on maximum junction temperature of 105°C.
THERMAL CHARACTERISTICS (1)
PARAMETER
484 BGA AT 2.5 W
UNITS
RθJA
Thermal resistance, junction-to-ambient (still air)
18
°C/W
RθJMA1
Thermal resistance, junction-to-ambient (1 m/s)
14.3
°C/W
RθJC
Thermal resistance, junction-to-case
6.8
°C/W
RθJB
Thermal resistance, junction-to-board
8
°C/W
(1)
Customer must check that heat removal is appropriate for the application to limit the junction temperature (TJ) aspecified in the
Recommended Operating Conditions. Conducting heat through the ground and power balls, or adding a heat sink and airflow, may be
needed to limit junction temperature.
ELECTRICAL CHARACTERISTICS
Describes the electrical characteristics for the baseband interface, multifunction I/O (MFIO), DPD clock and fast sync, MPU
and JTAG interfaces over recommended operating conditions. Device is production tested at 90°C for the given specification
and characterized at –40°C (unless otherwise noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
CMOS INTERFACE
VIL
CMOS voltage input, low
VIH
CMOS voltage input, high
VOL
CMOS voltage output, low
IOL = 2 mA
VOH
CMOS voltage output, high
IOH = –2 mA
2.4
|IPU|
Pullup current
VIN = 0 V
40
|IIN|
Leakage current
VIN = 0 or VIN = VDDSHV
2
100
0.8
V
VDDSHV
V
0.5
V
VDDSHV
V
200
μA
5
μA
DAC INTERFACE (DACP/N[15:0])
Vo(diff)
Vcomm
Output differential swing
Common mode
| VOD | = | VOH – VOL | (1)
(VOH + VOL) / 2
(1)
250
mV
1000
mV
LVDS INTERFACE (FB[35:0], DPDCLK/C, SYNCD/C)
VI
Input voltage range
VI(diff)
Input differential voltage,
|Vpos – Vneg|
RIN
Input differential impedance
0
0 < Vi < 2000 mV
1000 mV < VI < 1400 mV, FB[35:0] only
2000
250
mV
mV
90
80
120
Ω
1.7
A
POWER SUPPLY
Idyn
(1)
(2)
16
Core current
See (2)
HSTL output levels measured at 675 Mb/s delay and with 100-Ω load from P to N. Drive strength set to 0x360.
400-Mbps DAC signal, 200-Mhz DPD clock, maximum filtering, 70-Mhz BBPLL clock input
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SWITCHING CHARACTERISTICS
Describes the electrical characteristics for the baseband interface, MFIO[19,18]. Sync A, B, C, and BB Clock over
recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
MAX
UNIT
25
70
MHz
70
BASEBAND INTERFACE
fCLK(BB)
Baseband input clock frequency
GPP is ACTIVE
GPP is BYPASSED
25
tsu(BB)
Input data setup time before BBCLK↑
BB[15:0], BBFR, SYNCA, SYNCB, and SYNCC;
MFIO18/19
1.3
ns
th(BB)
Input data hold time after BBCLK↑
BB[15:0], BBFR, MFIO18/19
1.5
ns
th(SYNCA, -B, -C)
Input data hold time after BBCLK↑
Valid for SYNCA, SYNCB, and SYNCC
DutyCLK(BB)
Duty cycle
2
30%
ns
70%
1/fCLK(BB)
BBCLK
BB[15:0]
tsu(BB)
I(ch = 1, t = 1)
Q(ch = 1, t = 1)
Q(ch = N, t = 1)
I(ch = 1, t = 2)
th(BB)
BBFR
T0284-01
Figure 10. Baseband Timing Specifications
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DPD CLOCK AND FAST SYNC SWITCHING CHARACTERISTICS
MIN
MAX
UNIT
fCLK(DPD)
DPD input clock frequency
PARAMETER
TEST CONDITIONS
100
200
MHz
DutyCLK(DPD)
DPD input clock duty cycle
30%
70%
th(SYNCD)
Input hold time after DPDCLK↑
tsu(SYNCD)
Input setup time after DPDCLK↑
th(SYNCA, -B, -C)
Input hold time after DPDCLK↑
tsu(SYNCA, -B, -C)
Input setup time after DPDCLK↑
JitterCLK(DPD)
(1)
(2)
(2)
See (1)
0.2
ns
(1)
0.4
ns
2
ns
0.4
ns
See
Cycle-to cycle jitter
–2.5%
2.5%
Controlled by design and process
Jitter is based on a period of (1/(DPDClk × 2)) (for BUC Interp 1 or 2); (1/( DPDClk × 3)) (for BUC Interp 1.5 or 3).
DPDCLK
DPDCLKC
SYNCDC
SYNCD
tsu(SYNCD)
th(SYNCD)
SYNCA
SYNCB
SYNCC
tsu(SYNCA, -B, -C)
th(SYNCA, -B, -C)
T0286-01
Figure 11. DPD Clock and Fast Sync Timing Specifications
18
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MPU SWITCHING CHARACTERISTICS (READ)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
MAX
UNIT
tsu(AD)
ADDR setup time to RDB↓
WRB is HIGH
5
ns
tsu(CEB)
CEB setup time to RDB↓
WRB is HIGH
7
ns
tsu(OEB)
OEB setup time to RDB↓
WRB is HIGH
2
td(RD)
DATA valid time after RDB↓
WRB is HIGH
ADDR hold time to RDB↑
WRB is HIGH
th(RD)
2
OEB, CEB hold time to RDB↑
ns
ns
0
tHIGH(RD)
Time RDB must remain HIGH between READs.
WRB is HIGH (1)
tZ(RD)
DATA goes high-impedance after OEB↑ or RDB↑
WRB is HIGH (1)
(1)
ns
14
7
ns
7
ns
Controlled by design and process and not directly tested.
RDB
tHIGH(RD)
WRB
th(OEB)
tsu(OEB)
OEB
tsu(CEB)
CEB
tsu(AD)
ADDR
DATA
3-State
td(RD)
tZ(RD)
th(RD)
T0287-01
Figure 12. MPU READ Timing Specifications
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MPU SWITCHING CHARACTERISTICS (WRITE)
PARAMETER
TEST CONDITIONS
DATA and ADDR setup time to WRB↓
tsu(WR)
MAX
UNIT
5
CEB setup time to WRB↓
OEB and RDB are HIGH
7
OEB setup time to WRB↓
ns
2
DATA and ADDR hold time after WRB↑
th(WR)
MIN
OEB and RDB are HIGH
2
OEB and CEB hold time after WRB↑
ns
0
tlow(WR)
Time WRB and CEB must remain simultaneously LOW
OEB and RDB are HIGH
15
ns
thigh(WR)
Time CEB or WRB must remain HIGH between WRITEs
OEB and RDB are HIGH
10
ns
RDB
tlow(WR)
thigh(WR)
WRB
OEB
th(WR)
tsu(WR)
CEB
ADDR
DATA
T0288-01
Figure 13. MPU WRITE Timing Specifications
20
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JTAG SWITCHING CHARACTERISTICS
over operating free-air temperature range (unless otherwise noted)
TEST CONDITIONS PARAMETER
MIN
MAX
UNIT
50
MHz
fTCK
JTAG clock frequency
tp(TCKL)
JTAG clock low period
10
ns
tp(TCKH)
JTAG clock high period
10
ns
tsu(TDI)
Input data setup time before TCK↑
Valid for TDI and TMS
1
ns
th(TDI)
Input data hold time after TCK↑
Valid for TDI and TMS
6
ns
td(TDO)
Output data delay from TCK↓
8
ns
1/fTCK
TCK
tp(TCKH)
tp(TCKL)
TDI
tsu(TDI)
th(TDI)
TDO
td(TDO)
T0289-01
Figure 14. JTAG Timing Specifictions
TX SWITCHING CHARACTERISTICS
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
HSTL MODE – DDR ex. DAC5682
fCLK(DAC)
DAC output clock frequency
RL = 100 Ω (1)
300
MHz
tSKW(DAC)
DACCLK to DAC data
RL = 100 Ω (2)
TBD
ps
(1)
(2)
Because the output clock is DDR, the data rate is 2× the fCLK rate; fCLK(DAC) = (BUC Interp × DPDClk / 2).
tSKW(DAC) data clock-to-data is measured during characterization.
1/fCLK(DAC)
DACCLKC
DACCLK
DAC[15:0]P
I
Q
I
DAC[15:0]N
tSKW(DAC)
T0290-01
Figure 15. TX Timing Specifications (HSTL – DDR)
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TX SWITCHING CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
HSTL MODE – SDR ex. DAC5688
fCLK(DAC)
DAC output clock frequency
2-mA load (1)
200
MHz
td
DACCLK-to-DACData delay time
2-mA load (2)
1.5
ns
tho
DACCLK-to-DACData hold time
2-mA load (2)
(1)
(2)
1.5
ns
Because the output clock is SDR, the positive edge of the clock is used to register the data at the DAC receiver. The clock rate is limited
to 200 MHz.
td and tho data clock-to-data is measured during characterization.
DACCLKC
DACCLK
DAC[15:0]
I or Q
tho
td
T0448-01
Figure 16. TX Timing Specifications (HSTL – SDR)
ENVELOPE SWITCHING CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
DPDC
lk/2
MHz
MFIO CMOS – SDR to Envelope Modulator
fCLK(ENV)
ENVELOPE data output clock frequency
2-mA load (1)
td
ENVCLK-to-ENVData delay time
2-mA load (2)
tho
ENVCLK-to-ENVData hold time
2-mA load (2)
(1)
(2)
1.5
1.5
ns
ns
Envelope output is magnitude; this is a real output at a DPDClk/2 (100-MHz) rate.
td and tho data clock-to-data is measured during characterization.
ENVCLK
ENVDATA[15:0]
tho
td
T0449-01
Figure 17. Envelope Timing (MFIO – CMOS 3.3 V)
22
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SLWS218A – OCTOBER 2009 – REVISED OCTOBER 2009
LVDS SWITCHING CHARACTERISTICS
over recommended operating conditions (unless otherwise noted). The following table uses a shorthand nomenclature, NxM.
N means the number of differential pairs used to transmit data from one ADC, and M means the number of bits sent serially
down each LVDS pair. Thus, 8x2 means eight LVDS pairs, each containing 2 bits of information sent serially. NOTE: The
ADC clock rate must match the DPDClock rate for real feedback.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
200
MHz
16x1 SDR LVDS MODE ex. ADS5444
fCLK(ADC)
ADC interface clock frequency
See (1)
tsu(ADC[#]P)
Input data setup time before CLK↑
See (1)
(2)
300
ps
th(ADC[#]P)
Input data hold time after CLK↑
See (1)
(2)
600
ps
(3)
430
(1) (3)
260
8x2 DDR LVDS MODE ex. ADS5545, ADS6149
fCLK(ADCA)
ADCA interface clock frequency
See (1)
tsu(ADCA[#/2]P)
Input data setup time before CLK↑↓
See (1)
200
. For port A
ps
th(ADCA[#/2]P)
Input data hold time after CLK↑↓
See
fCLK(ADCB)
ADCB interface clock frequency
See (1)
tsu(ADCB[#/2]P)
Input data setup time before CLK↑↓
See (1)
(4)
800
ps
th(ADCB[#/2]P)
Input data hold time after CLK↑↓
See (1)
(4)
400
ps
(1)
(2)
(3)
(4)
. For port A
MHz
ps
200
. For port B
. For port B
MHz
Specifications are limited by GC5328 performance and may exceed the example ADC capabilities for the given interface.
Setup and hold measured for ADC[15:0]P, ADC[15:0]N valid for (VOD > 250 mV) to/from ADCCLK and ADCCLKC clock crossing
(VOD = 0).
Setup and hold measured for ADCA[7:0]P, ADCA[7:0]N valid for (VOD > 250 mV) to/from ADCACLK and ADCACLKC clock crossing
(VOD = 0).
Setup and hold measured for ADCB[7:0]P, ADCB[7:0]N valid for (VOD > 250 mV) to/from ADCBCLK and ADCBCLKC clock crossing
(VOD = 0).
1/fCLK(ADC)
CLK
CLKC
ADC[15:0]P
ADC[15:0]N
tsu(ADC[#]P)
th(ADC[#]P)
T0291-01
Figure 18. LVDS Timing Specification (16x1 SDR LVDS)
1/fCLK(ADCx)
CLK
CLKC
ADC[# bits/2]P
Even Bits
Odd Bits
Even Bits
Odd Bits
ADC[# bits/2]N
tsu(ADCx[#/2]P)
th(ADCx[#/2]P)
t=N
t=N+1
T0293-01
Figure 19. LVDS Timing Specification (8x2 DDR LVDS)
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GLOSSARY OF TERMS
3G
Third-generation (refers to next-generation wideband cellular systems that use CDMA)
3GPP
Third-generation partnership project (W-CDMA specification, www.3gpp.org)
3GPP2
Third-generation partnership project 2 (cdma2000 specification, www.3gpp2.org)
ACLR
Adjacent channel leakage ratio (measure of out-of-band energy from one CDMA carrier)
ACPR
Adjacent channel power ratio
ADC
Analog-to-digital converter
BW
Bandwidth
CCDF
Complementary cumulative distribution function
CDMA
Code division multiple access (spread spectrum)
CEVM
Composite error vector magnitude
CFR
Crest factor reduction
CMOS
Complementary metal oxide semiconductor
DAC
Digital-to-analog converter
dB
Decibels
dBm
Decibels relative to 1 mW (30 dBm = 1 W)
DDR
Dual data rate (ADC output format)
DSP
Digital signal processing or digital signal processor
DUC
Digital upconverter (usually provides the GC5328 input)
EVM
Error vector magnitude
FIR
Finite impulse response (type of digital filter)
I/Q
In-phase and quadrature (signal representation)
IF
Intermediate frequency
IIR
Infinite impulse response (type of digital filter)
JTAG
Joint Test Action Group (chip debug and test standard 1149.1)
LO
Local oscillator
LSB
Least-significant bit
Mb
Megabits (divide by 8 for megabytes MB)
MSB
Most-significant bit
MSPS
Megasamples per second (1×106 samples/s)
PA
Power amplifier
PAR
Peak-to-average ratio
PCDE
Peak code domain error
PDC
Peak detection and cancellation (stage)
PDF
Probability density function
RF
Radio frequency
RMS
Root mean square (method to quantify error)
SDR
Single data rate (ADC output format)
SEM
Spectrum emission mask
SNR
Signal-to-noise ratio (usually measured in dB or dBm)
UMTS
Universal mobile telephone service
W-CDMA
Wideband code division multiple access (synonymous with 3GPP)
WiBRO
Wireless broadband (Korean initiative IEEE 802.16e)
WiMAX
Worldwide Interoperability of Microwave Access (IEEE 802.16e)
24
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PACKAGE OPTION ADDENDUM
www.ti.com
12-Nov-2009
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
GC5328IZER
ACTIVE
BGA
ZER
Pins Package Eco Plan (2)
Qty
484
60
Pb-Free
(RoHS)
Lead/Ball Finish
SNAGCU
MSL Peak Temp (3)
Level-3-260C-168 HR
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
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incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited
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