TI ADS41 Wideband transmit-receive digital signal processor Datasheet

GC5330
GC5337
SLWS226 B – DECEMBER 2010 – REVISED JANUARY 2011
www.ti.com
Wideband Transmit-Receive Digital Signal Processors
Check for Samples: GC5330, GC5337
FEATURES
APPLICATIONS
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Integrated Transmit and Receive Digital IF
Solution
Up to 4 TX, 8 RX, Plus DPD Feedback
TX-Transmit Includes DUC, CFR, DPD, TX
Equalizer, and Bulk Upconverter
62-MHz TX Signal Bandwidth With Fifth-Order
DPD Correction
CFR: 6-dB PAR for WCDMA, 7-db LTE Signals
With EVM Meeting 3GPP Specs; Configurable
for All Major Wireless Infrastructure Standards
DPD: Memory Compensation, Typical ACLR
Improvement of 20 dB or More
RX-Receive Includes DC-Offset Cancellation,
Front-End and Back-End AGC, Bulk
Downconverter, RX Equalizer, I/Q Imbalance
Correction, DDC
4 DDUCs, 1–12 Channels per DDUC, Each
DDUC Can Be Programmed to TX or RX, at a
Common Resampler Rate – Multimode
Support
Seamless Interface to TI High-Speed Data
Converters
4 TX Aggregate Output to DACs up to
930 MSPS Complex
8 RX Aggregate Input From ADCs up to
1.24 GSPS Real
Supports Envelope Tracking Techniques
16-Tap (Complex) RX Equalizers
Two 4K Complex Word Capture Buffers for
Signal Analysis, Adaptive Filtering, and DPD
Algorithms
TMS320C6748 DPD Optimization Software
1.1-V Core, 3.3-V I/O CMOS, 1.8-V I/O LVDS
Power Consumption, 3.5 W Typical
484-Ball TE-PBGA Package, 23 mm × 23 mm
Multi-Standard Base Stations
3GPP (LTE, W-CDMA, TDS-CDMA)
MC-GSM
WiMAX and WiBro (OFDMA)
Multi-Carrier Power Amplifiers (MCPAs)
Wireless Infrastructure Repeaters
Up to 4 × 4 MIMO
DESCRIPTION
The GC533x is a wideband transmit and receive
signal processor that includes digital downconverter /
upconverter (DDUC), transmit, receive, and capture
buffer blocks. The transmit path includes crest factor
reduction (CFR), digital predistortion (DPD) and
associated feedback path, complex equalization, and
bulk upconversion.
The receive path includes wideband and narrowband
automatic gain control (AGC), bulk downconversion,
complex equalization, and I/Q imbalance correction.
The DDUC section consists of four identical DDUC
blocks, each supporting up to 12 channels. Each
channel has independent fractional resamplers and
NCOs to enable flexible carrier configurations.
Multi-mode/multi-standard
operation
can
be
supported by configuring the individual DDUC blocks
to different filtering and oversampling scenarios.
DAC3484
C6748
DSP
TRF3703/3720
Complex
TX
I/Q Mod
PA
I/Q Mod
PA
I/Q Mod
PA
I/Q Mod
PA
DAC
I/Q
DAC
I/Q
ADS61B49
FB
Baseband
Data
GC533x
DUC-CFR
DPD
DDC
Subsampled
Feedback
SW
ADC
Mixer/BPF
ADS62P49
RX
RX
ADC
Mixer/BPF
LNA
ADC
Mixer/BPF
LNA
ADC
Mixer/BPF
LNA
ADC
Mixer/BPF
LNA
Real
RX
ADS62P49
RX
RX
Real
RX
B0441-01
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.
© 2010–2011, Texas Instruments Incorporated
GC5330
GC5337
SLWS226 B – DECEMBER 2010 – REVISED JANUARY 2011
www.ti.com
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
DESCRIPTION (Continued)
The CFR block reduces the peak-to-average ratio (PAR) of the digital transmit signals, such as those used in
third-generation (3G) code division multiple access (CDMA) and orthogonal frequency-division multiple-access
(OFDMA) applications.
The DPD path with a 310-MHz DPD clock can be configured to support one antenna at 62 MHz, two antennas at
62 MHz each, or four antennas at 31 MHz each, all with an associated 5× DPD expansion bandwidth. The
GC533x DPD processor reduces power amplifier (PA) nonlinearity, e.g., as measured by adjacent-channel
leakage ratio (ACLR), by over 20 dB. By reducing the PAR of the digital signal and the PA nonlinearity, the
operational efficiency of follow-on power amplifiers can be substantially improved.
A higher DPD bandwidth is possible with reduced DPD performance. Several architectures that provide
performance and cost optimization are listed in Table 1
Table 1. Sample Configurations for GC5330 {GC5337}
Figure
TX Antenna
DPD Bandwidth
Figure 1
2-62 {74} MHz
310 {370} MHz
Figure 2
2-62 {74} MHz
310 {370} MHz
Figure 3
2-62 {74} MHz
310 {370} MHz
Figure 4
2-62 {74} MHz
310 {370} MHz
Figure 5
4-31 {37} MHz
155 {185} MHz
2
ET Support
Feedback
Subsampled real
RX Antenna
Other
2 typical at 250
Msps, up to 4 at
250 Msps
Lower-cost 2-antenna
solution
2 at 250Msps, 4
Full-rate real up to
2-antenna solution with
with lower-rate RX
1Gsps
full-rate real feedback
ADC
Subsampled
complex
2-envelope
tracking
2 at 250Msps, 4
2-antenna solution with
with lower-rate RX complex feedback, lower
ADC
subsampling ratio
2 at 250Msps, 4
2-antenna solution, with
Full-rate real up to
with lower-rate RX envelope tracking with
1Gsps
ADC
full-rate real feedback
Subsampled real
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4 at 250Msps, 8
Lower-cost 4 antenna
with lower-rate RX
solution
ADC
© 2010–2011, Texas Instruments Incorporated
Product Folder Link(s): GC5330 GC5337
GC5330
GC5337
SLWS226 B – DECEMBER 2010 – REVISED JANUARY 2011
www.ti.com
ANTENNA MODE EXAMPLE DIAGRAMS
C6748
DSP
DAC3283/3482
I/Q
I/Q
Baseband
Data
TRF3703/3720
Complex
TX
DAC
I/Q Mod
PA
DAC
I/Q Mod
PA
ADS41B49
GC533x
DUC-CFR
DPD
DDC
FB
ADC
Mixer/BPF
Subsampled
Feedback
SW
ADS62P49
RX
RX
ADC
LNA
Mixer/BPF
Real
RX
ADC
LNA
Mixer/BPF
B0442-01
Figure 1. Two-Antenna-Mode Subsampled-Feedback Diagram
C6748
DSP
DAC3283/3482
I/Q
I/Q
Baseband
Data
TRF3703/3720
Complex
TX
DAC
I/Q Mod
PA
DAC
I/Q Mod
PA
ADS5474
GC533x
DUC-CFR
DPD
DDC
RX
ADC
Mixer/BPF
Real
Feedback
SW
ADS62P49
RX
RX
ADC
Mixer/BPF
LNA
Real
RX
ADC
Mixer/BPF
LNA
B0443-01
Figure 2. Two-Antenna-Mode Full-Rate Real-Feedback Diagram
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3
GC5330
GC5337
SLWS226 B – DECEMBER 2010 – REVISED JANUARY 2011
C6748
DSP
www.ti.com
DAC3283/3482
I/Q
I/Q
TRF3703/3720
Complex
TX
DAC
I/Q Mod
PA
DAC
I/Q Mod
PA
ADS62P49
RX
Baseband
Data
GC533x
DUC-CFR
DPD
DDC
ADC
I/Q Demod
RX
Complex
Feedback
SW
ADC
ADS62P49
RX
RX
ADC
LNA
Mixer/BPF
Real
RX
ADC
LNA
Mixer/BPF
B0435-01
Figure 3. Two-Antenna-Mode Complex-Feedback Diagram
C6748
DSP
Env. Mod
DAC3484
TRF3703/3720
ET TX
DAC
I/Q Mod
PA
DAC
I/Q Mod
PA
I/Q
Env. Mod
Baseband
Data
GC533x
DUC-CFR
DPD
DDC
ADS5474
RX
ADC
Mixer/BPF
Real
Feedback
SW
ADS62P49
RX
ADC
Mixer/BPF
LNA
Real
RX
RX
ADC
Mixer/BPF
LNA
B0444-01
Figure 4. Two-Antenna-Mode, Envelope-Tracking, Full-Rate Real-Feedback Diagram
4
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Product Folder Link(s): GC5330 GC5337
GC5330
GC5337
SLWS226 B – DECEMBER 2010 – REVISED JANUARY 2011
www.ti.com
DAC3484
C6748
DSP
TRF3703/3720
Complex
TX
I/Q Mod
PA
I/Q Mod
PA
I/Q Mod
PA
I/Q Mod
PA
DAC
I/Q
DAC
I/Q
ADS61B49
FB
Baseband
Data
GC533x
DUC-CFR
DPD
DDC
Subsampled
Feedback
SW
ADC
Mixer/BPF
ADS62P49
RX
RX
ADC
Mixer/BPF
LNA
Real
RX
ADC
Mixer/BPF
LNA
Mixer/BPF
LNA
ADS62P49
RX
RX
ADC
Real
RX
ADC
Mixer/BPF
LNA
B0441-01
Figure 5. Four-Antenna-Mode Subsampled Real-Feedback Example Diagram
GENERAL DESCRIPTION
The GC533x is a wideband transmit and receive signal processor that includes digital downconverter/upconverter
(DDUC), transmit, receive, and capture buffer blocks. The transmit path includes crest factor reduction (CFR),
digital predistortion (DPD) and associated feedback path, complex equalization, and bulk upconversion. The
receive path includes wideband and narrowband automatic gain control (AGC), bulk downconversion, complex
equalization, and I/Q imbalance correction. The GC5337 is a higher-speed version of the GC5330 that has the
same package, but with interfaces that can provide more processing performance for higher-bandwidth
applications. In the descriptions, the GC5337 differences are shown with { } values.
The architecture supports different RX, TX, and feedback modes of operation. This provides for many
configurations to optimize performance and cost.
• RX – real or complex input
• TX – real, complex, complex with envelope tracking
• Feedback – subsampled real, full-rate real, full-rate complex
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GC5330
GC5337
SLWS226 B – DECEMBER 2010 – REVISED JANUARY 2011
www.ti.com
The RX path can be configured for one or two multichannel ADC input ports. The RX block provides each ADC
channel with a front-end AGC, IQ demodulation correction, real-to-complex conversion, complex mixing,
decimation, and complex equalization. The RX block output is input to the DDUC block. The output of the DDUC
block goes through gain and back-end AGC and is formatted for the baseband output.
There are four DDUC blocks. Each can be used for the RX DDC downconversion or TX DUC upconversion, one
at a time. The DDUC has a complex mixer, cascade integrator comb filter, resampler, and a programmable FIR
filter. Each DDUC can support 1 to 12 channels.
The TX path can be configured for one, two, or four antenna streams. In addition, with one or two antenna
streams, an envelope modulator output is available. The DAC and envelope modulator share the same output
ports. The TX input is from the baseband input, through the DDUC to create complex antenna streams. The CFR
block provides for gain adjustment, peak reduction, and peak limiting. The CFR block peak power reduction and
follow-on circular limiter provide the headroom to apply the DPD correction, and to lower the peak power results
for more power amplifier efficiency. Additional interpolation stages after CFR expand the antenna stream
bandwidth to the DPD bandwidth.
The DPD has both high-performance (more correction) and high-bandwidth (more bandwidth) modes. The
high-bandwidth mode supports 62 MHz {74 MHz} for one or two antenna streams, and 31 MHz {37 MHz} for four
antenna streams with fifth-order expansion bandwidth. The high-performance mode supports one antenna at 62
MHz {74 MHz}, two antennae at 31 MHz {37 MHz}, or four antennae at 15.5 MHz {18.5 MHz}. The GC533x DPD
processor provides phase correction, gain correction, and nonlinear feedforward correction for each TX stream.
The spectral emission or ACP performance is improved by 20 dB or more.
Specialized capture logic collects the RX input, feedback input, RX output, DPD input, and DPD output for the
DSP processor to perform the adaption algorithm. The capture logic can also be used for performance
monitoring and power measurement.
AVAILABLE OPTIONS
6
PART NUMBER
TC
PACKAGE
THERMAL PROPERTIES
GC5330IZEV
–40°C to 85°C
484 ball 23-mm × 23-mm PBGA
Heat transfer through package top
GC5337IZEV
–40°C to 85°C
484 ball 23-mm × 23-mm PBGA
Heat transfer through package top
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GC5330
GC5337
SLWS226 B – DECEMBER 2010 – REVISED JANUARY 2011
www.ti.com
GC5330, GC5337
24 LVDS (1.8V)
Power
Meter,
per
Channel
Farrow
1–1024´
beAGC
per
Channel
ET
NCO
24 LVDS (1.8V) Baseband
Interface
FIR
1´,
2´
40 LVDS (1.8V)
TX
1–2 Streams
1–12 Channel DDUC Block
(config as TX or RX, showing TX)
CIC
1–3´
Mux
and
Sum
(TX)
or
Dist
(RX)
X
Capture Buffer A
UC
1/2´
CFR
DPD
and
TX
Eq
TX
IF
Mux
and
Sum
X
BUC
IF NCO
2´
Includes
40% BW,
interp
before or 90 dB stop
after CFR,
80% BW,
90 dB stop
1/2/3/4´
80% BW,
90 dB stop;
90% BW,
80 dB stop
40 LVDS (1.8V)
1–4 TX Streams
Up to 8 DACs
(2 40-Pin Ports)
DVGA
Format/
GPIO
16 CMOS (3.3V)
Capture Buffer B
TX
Complex
Gain per
Channel
ADC
interface
(port
AB)
Interval Based Power Meter
Running Avg Power Meter
RX 1/2/4 Streams
I/Q
Imbal
Correction
Eq
(16
Taps)
BDC
IF
NCO
Switch
R2C
feAGC
DC
Offset
Cancel
ADC
interface
(port C)
1/2/4/8/16´
When I/Q correction
enabled, IF NCO is disabled
Control and Sync CMOS (3.3 V)
16
TX
Format
and
DAC
Interface
8
uP data uP addr
4
uP ctrl
2
INT
TESTMOD,
RESET
HighSpeed
Sync,
Clocks
JTAG CMOS (3.3 V)
2
Up to 8 ADCs
(2 30-Pin Ports)
60 LVDS (1.8V)
1 ADC
(1 16-Pin Port)
DPD clk
2 LVDS
Sync A, B in
4 LVDS
Sync out
2 LVDS
LVDS
showing
the number
of pins;
each signal
is a diff pair
4
SPI en, SPIDIO SPIDO
SPI clk
(SPARE)
60 LVDS (1.8V)
JTAG
B0445-01
NOTE: UC1 and UC2 are for CFR interpolation; UC2 can only be used if UC1 is also used.
Figure 6. GC533x Block Diagram
GC533x Introduction
The GC533x is a flexible transmit and receive digital signal processor that includes receiver and transmitter
blocks, digital downconverter / upconverter (DDUC) blocks, crest factor reduction (CFR) and digital predistortion
(DPD) engines, flexible LVDS data converter and baseband interfaces, and capture buffers for DPD and adaptive
filtering algorithms.
Each of the four DDUC blocks can be configured as either a digital downconverter (DDC) or a digital upconverter
(DUC). Typically, a system can be implemented as both TX and RX, with both DDC and DUC functions. The
DDUC blocks provide programmable FIR filters with flexible numbers of taps, depending on signal bandwidth and
number of channels, as well as fractional resamplers, CIC filters, and complex mixers. The DDUC complex
mixers support static or hopping tuning functions.
beAGC after the DDC is part of the baseband interface. Static gain is applied in the BB block for both the DDC
output and DUC input.
The receiver block provides dc offset correction, front-end AGC, real-to-complex conversion, complex mixing,
decimating filters, a complex equalizer, and a blind RX IQ imbalance correction function.
The CFR block reduces the peak-to-average ratio (PAR) of complex, arbitrary TX signals. Reducing the PAR of
the TX signal allows wireless-infrastructure (WI) base stations and repeaters to use smaller and lower-cost
multi-carrier power amplifiers (MCPAs).
The DPD block can process one or two TX streams at 62 MHz {74 MHz} or four TX streams at 31 MHz {37 MHz}
each, with fifth-order nonlinear correction. The DPD engine uses a companion TI DSP TMS320C6748 to collect
the reference and feedback data, calculate the feedforward correction, and update the GC533x registers.
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SLWS226 B – DECEMBER 2010 – REVISED JANUARY 2011
www.ti.com
In WI applications, the GC533x meets multi-carrier 3G and 4G performance standards (PCDE, composite EVM,
and ACLR) at PAR levels down to 6 dB for WCDMA and 7 dB for LTE, and improves the ACLR by over 20 dB at
the PA output. The GC533x integrates easily into the transmit/receive signal chain between Texas Instruments’
high-performance data converters and baseband processors such as the TI TMS320C64xx family. In wireless
repeater applications, the GC533x can provide seamless interfaces to TI data converters, along with receive and
transmit filtering, DDC, and DUC functions.
The GC533x is extremely flexible and can be used in system architectures with different signal types and
TX-by-RX antenna configurations such as 2×2, 2×4, 4×4, and 4×8.
The GC533x EVM system provides an example sector transmit-receive signal chain solution, from the
multi-carrier baseband to the RF antenna.
ABSOLUTE MAXIMUM RATINGS
over recommended operating free-air temperature range (unless otherwise noted) (1)
MIN
MAX
UNIT
VDD
Core supply voltage
–0.3
1.32
V
VDDA
PLL analog voltage
–0.3
2
V
VDDS
Digital supply voltage for TX
–0.3
2
V
VDDSHV
Digital supply voltage
–0.3
3.6
V
VIN
Input voltage (under/overshoot)
–0.5
VDDSHV + 0.5
Clamp current for an input/output
–20
20
mA
Storage temperature
–65
140
°C
Tstg
(1)
ESD classification
Class 2 (2.5 kV HBM, 500 V CDM, 150 V MM)
Moisture sensitivity
Moisture sensitivity Class 3 (1 week floor life at 30°C / 60% H)
V
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating
Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
RECOMMENDED OPERATING CONDITIONS
MIN
Core supply voltage (1)
VDD
310 MHz, 5.7 A max.
(2) (1)
{370 MHz} (3)
TYP MAX
1.05
1.1
1.15
1.1
1.125
1.15
UNIT
V
VDDA
Analog supply for PLLs
60 mA max. (each) (2)
1.71
1.8
1.89
VDDS
Digital supply voltage for LVDS I/O
700 mA max. (2)
1.71
1.8
1.89
VDDSHV
Digital supply voltage CMOS I/O
PC board design dependent
3.15
3.3
3.45
V
TC
Case temperature
–40
30
90
°C
TJ
Junction temperature
105
°C
(1)
(2)
(3)
(4)
8
i (4)
V
Production tested hot using checksum at 310 MHz and maximum supplies. Power scales linearly with frequency with a dc consumption
around 350 mA typical, 700 mA worst case.
Chip specifications are production tested to 90°C case temperature. QA tests are performed at 85°C.
Power consumption is a strong function of the configuration. A calculator is available to estimate power for a specific configuration.
Reliability calculations presume junction temperature 105°C or below. Operation above 105°C junction temperature reduces product
lifetime.
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GC5330
GC5337
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www.ti.com
THERMAL INFORMATION
GC5330
THERMAL METRIC
ZEV
UNIT
484 PINS
Junction-to-ambient thermal resistance (1)
θJA
(2)
15.4
°C/W
θJCtop
Junction-to-case (top) thermal resistance
2.1
°C/W
θJB
Junction-to-board thermal resistance (3)
7.6
°C/W
ψJT
Junction-to-top characterization parameter (4)
0.5
°C/W
ψJB
Junction-to-board characterization parameter
(5)
7.5
°C/W
θJCbot
Junction-to-case (bottom) thermal resistance (6)
N/A
°C/W
(1)
(2)
(3)
(4)
(5)
(6)
The junction-to-ambient thermal resistance under natural convection is obtained in a simulation on a JEDEC-standard, high-K board, as
specified in JESD51-7, in an environment described in JESD51-2a.
The junction-to-case (top) thermal resistance is obtained by simulating a cold plate test on the package top. No specific
JEDEC-standard test exists, but a close description can be found in the ANSI SEMI standard G30-88.
The junction-to-board thermal resistance is obtained by simulating in an environment with a ring cold plate fixture to control the PCB
temperature, as described in JESD51-8.
The junction-to-top characterization parameter, ψJT, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining θJA, using a procedure described in JESD51-2a (sections 6 and 7).
The junction-to-board characterization parameter, ψJB, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining θJA , using a procedure described in JESD51-2a (sections 6 and 7).
The junction-to-case (bottom) thermal resistance is obtained by simulating a cold plate test on the exposed (power) pad. No specific
JEDEC standard test exists, but a close description can be found in the ANSI SEMI standard G30-88.
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GC5330
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www.ti.com
Pin Assignment and Descriptions (Top View)
1
A
NC
2
3
4
5
7
6
BBIN5P BBIN4P BBIN3P BBIN1P SPIDENB SPICLK
8
9
10
11
12
13
14
15
CEB
UPA5
UPA2
UPD15
UPD12
UPD8
UPD5
UPD1
VSSA2 SYNCBN
UPD0
16
18
19
20
21
22
SYNC
OUTN
SYNC
OUTP
TXA1N
TXA2P
NC
A
VDDA2 SYNCBP TXA0N
TXA1P
TXA2N
TXA5N
B
17
B
BBIN7N BBIN7P BBIN5N BBIN4N BBIN3N BBIN1N SPIDIO INTERRPT
UPA6
UPA3
WEB
UPD13
UPD9
UPD6
UPD2
C
BBIN8N BBIN8P BBIN6P BBIN6N
VSSA1 BBIN2P BBIN0P EMIFENA
UPA7
UPA4
UPA0
UPD14
UPD10
UPD7
UPD3
SYNCAPDPDCLKP TXA0P
TXA3P
TXA4P
TXA4N
TXA5P
C
VDDA1 BBIN2N BBIN0N
VSS
OEB
VSS
UPA1
VSS
UPD11
VSS
UPD4
SYNCAN DPDCLKN TXA3N
TXA6N
TXA7N
TXA8N
TXA9P
D
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
NC
NC
TXA6P
TXA7P
TXA8P
TXA9N
E
VDD
VDDSHV1
VDD
VDDSHV1
VDD
VDDSHV1
VDD
VDDS1
NC
VDD
TXA11N TXA11P TXA10N TXA10P
F
VDD
TXA13P TXA13N TXA12P TXA12N
G
VDDS1 TXA15P TXA15N TXA14N TXA14P
H
TXA17P TXA17N TXA16N TXA16P
J
VDDS1 TXA19N TXA19P TXA18N TXA18P
K
D
NC
BBIN9N BBIN9P
NC
E
BBOUT0P BBIN10P BBIN10N BBIN11P BBIN11N
VDD
F
BBOUT0N BBOUT2N BBOUT2P BBOUT1N BBOUT1P
NC
G BBOUT4N BBOUT4P BBOUT3N BBOUT3P VDDS2
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
VDDS2 VDDSHV1
H BBOUT6N BBOUT6P BBOUT5N BBOUT5P
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
J
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
TXB1P
TXB1N
TXB0P
TXB0N
L
M RXA13N RXA12P RXA11N RXA11P VDDS2
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDDS1
TXB3P
TXB3N
TXB2P
TXB2N
M
N RXA12N RXA10P RXA9N
BBOUT8N BBOUT8P BBOUT7N BBOUT7P
K BBOUT10NBBOUT10P BBOUT9N BBOUT9P VDDS2
L
RXA13P RXA14N RXA14P BBOUT11P BBOUT11N
VDD
RXA9P
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
TXB5P
TXB5N
TXB4P
TXB4N
N
P
RXA10N RXA8N
RXA8P
RXA7N
RXA7P
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
TXB7P
TXB7N
TXB6P
TXB6N
P
R
RXA6N
RXA6P
RXA5N
RXA5P
VDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDDS1
TXB9P
TXB9N
TXB8P
TXB8N
R
T
RXA4N
RXA3N
RXA3P
RXA2N
RXA2P
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
TXB11P TXB11N TXB10P TXB10N
T
U
RXA4P
RXA1P
RXA0N
RXA0P
VDD
NC
VDDS2
VDD
VDDSHV2
VDD
VDDSHV2
VDD
VDDSHV2
VDD
VDD
VDDS1
NC
VDD
TXB13P TXB13N TXB12P TXB12N
U
V
RXA1N RXB14N RXB10N RXB10P
NC
NC
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
NC
NC
TXB15P TXB15N TXB14N TXB14P
V
RXB6P
RXB6N
RXB4P
RXB2P
VPP
VSS
VPP
VSS
DVGA6
VSS
TDO
TMS
RXC6N
RXC4N
NC
TXB17P TXB17N TXB16P TXB16N W
RXB13N RXB12N RXB8N
RXB8P
RXB5P
RXB4N
RXB2N VDDMON RESETB DVGA13 DVGA10 DVGA7
DVGA3
DVGA0
TDI
RXC6P
RXC5N
RXC4P TXB19N TXB19P TXB18N TXB18P
AA RXB12P RXB11P RXB9P
RXB7N
RXB5N
RXB3P
SPIDO
RXB1N VSSMON (SPARE) DVGA14 DVGA11 DVGA8
DVGA4
DVGA1
TRSTB
RXC7N
RXC5P
RXC3P
RXC2N
RXC2P
RXC0N
NC
AA
RXB11N RXB9N
RXB7P
NC
RXB3N
RXB1P
RXB0P
RXB0N TESTMOD DVGA15 DVGA12 DVGA9
DVGA5
DVGA2
TCK
RXC7P
RXC3N
RXC1N
RXC1P
RXC0P
NC
AB
4
5
6
7
8
14
15
16
17
18
19
20
21
22
W RXB14P RXB13P
Y
AB
NC
1
2
NC
3
= 1.1 V
9
= 1.8 V, 3.3 V
10
11
12
13
Y
= GND
P0131-01
Figure 7. GC533x Pinout (Top View)
10
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Pin Functions
NAME
NUMBER
TYPE
DESCRIPTION
POWER AND BIASING
VDD
E6, E7, E8, E9, E10, E11, E12, E13, E14, E15, E16, F9,
F11, F13, F15, F18, G18, H5, J5, J18, L18, N5, N18, P18,
R5, T18, U5, U8, U10, U12, U14, U15, U18, V7, V8, V9,
V10, V11, V12, V13, V14, V15, V16
PWR
1.1-V power supply
VDDSHV2
U9, U11, U13
PWR
3.3-V power supply for CMOS I/O
VDDSHV1
F8, F10, F12, F14
PWR
3.3-V power supply for CMOS I/O
VDDS1
F16, H18, K18, M18, R18, U16,
PWR
1.8-V power supply for LVDS I/O
VDDS2
F7, G5, K5, M5, U7
PWR
1.8-V power supply for LVDS I/O
VPP
W8, W10
PWR
1.1-V E-fuse supply, connect to VDD
VDDMON
Y8
NC
Do not connect, internal monitor point
VSSMON
AA8
NC
Do not connect, internal monitor point
VDDA2
B17
PWR
1.8-V power for PLL (requires filtering)
VDDA1
D5
PWR
1.8-V power for PLL (requires filtering)
VSSA2
A16
PWR
Ground for PLL (requires filtering)
VSSA1
C5
PWR
Ground for PLL (requires filtering)
VSS
D8, D10, D12, D14, G6, G7. G8, G9, G10, G11, G12, G13,
G14, G15, G16, G17, H6, H7, H8, H9, H10, H11, H12, H13,
H14, H15, H16, H17, J6, J7, J8, J9,J10, J11, J12, J13, J14,
J15, J16, J17, K6, K7, K8, K9, K10, K11, K12, K13, K14,
K15, K16, K17, L6, L7, L8, L9, L10, L11, L12, L13, L14,
L15, L16, L17, M6, M7, M8, M9, M10, M11, M12, M13, M14,
M15, M16, M17, N6, N7, N8, N9, N10, N11, N12, N13, N14,
N15, N16, N17, P6, P7, P8, P9, P10, P11, P12, P13, P14,
P15, P16, P17, R6, R7, R8, R9, R10, R11, R12, R13, R14,
R15, R16, R17, T6, T7, T8, T9, T10, T11, T12, T13, T14,
T15, T16, T17,W9, W11, W13
PWR
Ground
NC
E17, E18, F6, F17, U6, U17, V5, V6, V17, V18
NC
No connection. Recommend connecting to ground
NC
A1, A22, D1, D4, W3, W18, AA22, AB1, AB5, AB22,
NC
No connection
BASEBAND INPUT/OUTPUT
BBIN[11:0]P
E4, E2, D3, C2, B2, C3, A2, A3, A4, C6, A5, C7
I
Baseband input – LVDS positive
BBIN[11:0]N
E5, E3, D2, C1, B1, C4, B3, B4, B5, D6, B6, D7
I
Baseband input – LVDS negative
BBOUT[11:0]P
L4, K2, K4, J2, J4, H2, H4, G2, G4, F3, F5, E1
O
Baseband output – LVDS positive
BBOUT[11:0]N
L5, K1, K3, J1, J3, H1, H3, G1, G3, F2, F4, F1
O
Baseband output – LVDS negative
TX DAC INTERFACE
TXA[19:0]P
K20, K22, J19, J22, H19, H22, G19, G21, F20, F22, D22,
E21, E20, E19, C22, C20, C19, A21, B20, C18
O
DAC TX port A – LVDS positive
TXA[19:0]N
K19, K21, J20, J21, H20, H21, G20, G22, F19, F21, E22,
D21, D20, D19, B22, C21, D18, B21, A20, B19
O
DAC TX port A – LVDS negative
TXB[19:0]P
Y20, Y22, W19, W21, V19, V22, U19, U21, T19, T21, R19,
R21, P19, P21, N19, N21, M19, M21, L19, L21
O
DAC TX port B – LVDS positive
TXB[19:0]N
Y19, Y21, W20, W22, V20, V21, U20, U22, T20, T22, R20,
R22, P20, P22, N20, N22, M20, M22, L20, L22
O
DAC TX port B – LVDS negative
RX and FB ADC INTERFACE
RXA[14:0]P
L3, L1, M2, M4, N2, N4, P3, P5, R2, R4, U1, T3, T5, U2, U4
I
ADC receive port A – LVDS positive
RXA[14:0]N
L2, M1, N1, M3, P1, N3, P2, P4, R1, R3, T1, T2, T4, V1, U3
I
ADC receive port A – LVDS negative
RXB[14:0]P
W1, W2, AA1, AA2, V4, AA3, Y4, AB4, W4, Y5, W6, AA6,
W7, AB7, AB8
I
ADC receive port B – LVDS positive
RXB[14:0]N
V2, Y1, Y2, AB2, V3, AB3, Y3, AA4, W5, AA5, Y6, AB6, Y7,
AA7, AB9
I
ADC receive port B – LVDS negative
RXC[7:0]P
AB17, Y16, AA17, Y18, AA18, AA20, AB20, AB21
I
ADC receive port C – LVDS positive
RXC[7:0]N
AA16, W16, Y17, W17, AB18, AA19, AB19, AA21
I
ADC receive port C – LVDS negative
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Pin Functions (continued)
NAME
NUMBER
TYPE
DESCRIPTION
DVGA INTERFACE
DVGA[15:0]
AB11, AA10, Y10, AB12, AA11, Y11, AB13, AA12, Y12,
W12, AB14, AA13, Y13, AB15, AA14, Y14
O
MPU INTERFACE
UPD[15:0]
A11, C12, B12, A12, D13, C13, B13, A13, C14, B14, A14,
D15, C15, B15, A15, B16
I/O
UPA[7:0]
C9, B9, A9, C10, B10, A10, D11, C11
I
WEB
B11
I
Write enable, active-low
EMIFENA
C8
I
EMIFENA switches between address/data µP
access and SPI access. Its value may be changed
at any time, but both address/data access and SPI
access must be idle during the change. Logic 1 =
EMIF, logic 0 = SPI pin has internal pullup.
OEB
D9
I
Read and output enable, active-low
CEB
A8
I
Chip enable, active-low
I
JTAG reset (active-low); pull down if JTAG is not
used.
JTAG INTERFACE
TRSTB
AA15
TMS
W15
I
JTAG mode select
TDO
W14
O
JTAG data out
TDI
Y15
I
JTAG data in
TCK
AB16
I
JTAG clock
SPIDENB
A6
I
Serial interface enable
SPICLK
A7
I
Serial interface clock
SPIDIO
B7
I/O
Serial interface data
SPIDO(SPARE)
AA9
O
Serial interface data out in four-wire SPI mode
SPI INTERFACE
MISCELLANEOUS
TESTMOD
AB10
I
Test mode for GC533x, typically grounded
RESETB
Y9
I
Chip reset – required – active-low
INTERRPT
B8
O
Output interrupt
DPDCLKP
C17
I
DPD CLK input – LVDS positive
DPDCLKN
D17
I
DPD CLK input – LVDS negative
SYNCOUTP
A19
O
Sync output – LVDS positive
SYNCOUTN
A18
O
Sync output – LVDS negative
SYNCAP
C16
I
Sync input A – LVDS positive
SYNCAN
D16
I
Sync input A – LVDS negative
SYNCBP
B18
I
Sync input B – LVDS positive
SYNCBN
A17
I
Sync input B – LVDS negative
Ferrite Bead
R=0Ω
1.8V
VDDA1 or VDDA2
50 Ω
C = 0.1 μF
C = 0.01 μF
R=0Ω
GND
50 Ω
VSSA1 or VSSA2
Ferrite Bead
S0510-01
NOTE: 0-Ω R0603 resistor is used to accommodate series resistor if needed.
Figure 8. GC533x PLL Filtering
12
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The two GC533x PLLs require a filtered power supply. The supply can be generated by filtering the digital supply
(VDDS1, VSSA1, VDDS2, and VSSA2). A representative filter is shown in Figure 8. The two PLLs should have
separate filters that are located as close as is 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).
Sub-Chip Descriptions
Figure 9 shows the TX functional block diagram, and Figure 10 shows the RX functional block diagram. Note that
each figure shows up to four DUC or DDC blocks in the TX or RX paths, and there are a total of four DDUC
blocks that may be configured as either DUC or DDC each.
TX Block
1–12 Channel DUC Block
TX BB
TX BB Input Formatter
NCO
FIR
1x, 2x
Farrow
1–1024x
CIC
1–3x
X
1–2 Streams
Mux
and
Sum
UC
1/2x
CFR
80% BW,
90 dBstop
UC
1/2/4x
DPD
IF
NCO
BUC
IF
Sum
DAC Output Formatter
Envelope
Tracking
Block
1 to 4 Tx
Streams
40% BW, Includes
90 dBstop 16-tap Eq
1/2/3/4x
80% BW,
90 dBstop;
90% BW,
80% dB stop
B0446-01
Figure 9. TX Functional Block Diagram
1/2/4 Streams
RX BB
RX BB Output Formatter
NCO
FIR
1´, 2x
Farrow
1–1024´
CIC
1–3´
I/Q
Imbalance
Correction
X
Mux
RX
Equalizer
16 Taps
X
BDC
1/2/4/8/16´
When I/Q
correction
enabled,
IF NCO
is disabled
IF
Mux
IF NCO
X
R2C;
Format;
feAGC;
DC Offset
Correction
ADC Input Formatter
RX Block
1–12 Channel DDC Block
1 to 9
ADC
Inputs
DVGA Outputs
IF NCO
B0447-01
Figure 10. RX Functional Block Diagram
TX Baseband Input Formatter
The TX baseband (BB) input-formatter block accepts TX baseband inputs from the FPGA or baseband processor
and formats them for the DUC blocks. There are 12 unidirectional LVDS pairs for the TX input formatter, and
their function depends on the operational mode. There are three operational modes for the TX BB input
formatter: byte mode (B, 8 or 9 bits), nibble mode (N, 4 bits), and serial mode (S, 2 bits) to allow multiple BB
input rates. The GC533x can accept up to three different BB input data rates. Table 2 and Table 3 summarize
each mode and the pin assignments. In Table 3, BBIN[X] is the BBIN differential pair (assumed positive and
negative connections), and BB0, BB1, and BB2 represent three different TX baseband ports at arbitrary rates.
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Table 2. TX BB Formatter Modes
MODE
DESCRIPTION
Total Number of Interface Pins
Maximum Complex Interface Rate per Channel
N is the number of channels.
1B
Byte mode, 1 interface rate
10 or 11 = 8 or 9 data + 1 clk + 1
sync
(Clk × 4/4)/N; maximum 192.31 MSPS total (for all
channels)
1N
Nibble mode, 1 interface rate
6 = 4 data + 1 clk + 1 sync
(Clk × 4/8)/N; maximum 125 (Nibble 0), 96.15 (Nibble
1) MSPS total
1S
Serial mode, 1 interface rate
4 = 2 data + 1 clk + 1 sync
(Clk × 4/16)/N; maximum 48.07 MSPS total
2N
Nibble mode, 2 interface rates
12 = 4 data + 1 clk + 1 sync + 4
data + 1 clk + 1 sync
(Clk × 4/8)/N × 2; maximum 221.15 MSPS total
2N’ (1)
Nibble + byte mode, 2 interface
rates,
RX-ADC input pins used for
byte-mode port.
16 = 4 data + 1 clk + 1 sync + 8
data + 1 clk + 1 sync
Nibble port: (Clk × 4/8)/N; maximum 125 MSPS total
Byte port: (Clk × 2/4)/N; maximum 125, 250 MSPS
total
2S
Serial mode, 2 interface rates
8 = 2 data + 1 clk + 1 sync + 2 data
+ 1 clk + 1 sync
(Clk × 4/16)/N; maximum 96.15 MSPS total
3S
Serial mode, 3 interface rates
12 = 2 data + 1 clk+1 sync + 2 data (Clk × 4/16)/N; maximum 144.23 MSPS total
+ 1 clk + 1 sync + 2 data + 1 clk + 1
sync
(1)
2N’ is the only configuration that allows a special mode to re-use RX input port A as baseband TX inputs
Table 3. TX BB Pin Assignments
LVDS PAIR BBI[11:0]
BYTE MODE
NIBBLE MODE
SERIAL MODE
BBIN[0] pos. and neg.
BB0_DATA_0
BB0_DATA_0
BB0_DATA_0
BBIN[1] pos. and neg.
BB0_DATA_1
BB0_DATA_1
BB0_DATA_1
BBIN[2] pos. and neg.
BB0_DATA_2
BB0_SYNC
BB0_SYNC
BBIN[3] pos. and neg.
Spare
BB0_CLOCK
BB0_CLOCK
BBIN[4] pos. and neg.
BB0_DATA_3
BB0_DATA_2
BB1_DATA_0
BBIN[5] pos. and neg.
BB0_DATA_4
BB0_DATA_3
BB1_DATA_1
BBIN[6] pos. and neg.
BB0_SYNC
BB1_SYNC
BB1_SYNC
BBIN[7] pos. and neg.
BB0_CLOCK
BB1_CLOCK
BB1_CLOCK
BBIN[8] pos. and neg.
BB0_DATA_5
BB1_DATA_0
BB2_DATA_0
BBIN[9] pos. and neg.
BB0_DATA_6
BB1_DATA_1
BB2_DATA_1
BBIN[10] pos. and neg.
BB0_DATA_7
BB1_DATA_2
BB2_SYNC
BBIN[11] pos. and neg.
BB0_DATA_8
BB1_DATA_3
BB2_CLOCK
Number of BBdata streams
1
2
3
Number of DDR clocks to transfer 1 complex sample
2
4
8
The actual data transfer rate in nibble mode is 2 times higher than the byte mode for the same total throughput. If
two ports are required (e.g., to support two different sample rates), and a lower speed on the interface is desired,
the GC533x can re-use the RX ADC input port A as a baseband TX input bus. RX ADC port A has 15 pairs of
LVDS input pins and supports one set of baseband input data in byte mode. When RX port A is used as a
baseband TX input, it cannot be also used as an RX input port.
The baseband interface supports a full-clock or gated-clock format. These formats are shown in Figure 11
The mapping for the RX port A pins when in BB TX input mode is:
• RXA14: clock
• RXA13: sync
• RXA12–5: BB0_DATA7–0
14
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BBIN Clk 0
BBIN Sync 0
I0-O
I0-E
Q0-O
Q0-E
I1-O
I1-E
Q1-O
Q1-E
In-O
In-E
Qn-O
Qn-E
00
I0-O
I0-E
Q0-O
Q0-E
Mode 1B
BBIN Data 0
‘n’ can be up to 47, ‘O’ is odd numbered bits (1, 3, 5, ...), ‘E’ is even numbered bits (0, 2, 4, ...)
BBIN Clk 0
BBIN Sync 0
I0-A
I0-B
I0-C
I0-D
Q0-A
Q0-B
Q0-C
Q0-D
In-A
In-B
In-C
In-D
Qn-A
Qn-B
Qn-C
Qn-D
00
I0-A
BBIN Data 0
Mode 1N (1 Rate)
Mode 2N (2 Rates)
BBIN Clk 1
BBIN Sync 1
I0-A
I0-B
I0-C
I0-D
Q0-A
Q0-B
Q0-C
Q0-D
In-A
In-B
In-C
In-D
Qn-A
Qn-B
Qn-C
Qn-D
00
I0-A
BBIN Data 1
‘n’ can be up to 47, ‘A’ is 4 MSBs, ‘B’ is next 4 bits, ‘C’ is next 4 bits and ‘D’ is 4 LSBs
BBIN Clk 0
BBIN Sync 0
I0-A
I0-B
I0-C
I0-D
I0-E
I0-F
I0-G
I0-H
Qn-A
Qn-B
Qn-C
Qn-D
Qn-E
Qn-F
Qn-G
Qn-H
00
I0-A
BBIN Data 0
BBIN Clk 1
BBIN Sync 1
I0-A
I0-B
I0-C
I0-D
I0-E
I0-F
I0-G
I0-H
Qn-A
Qn-B
Qn-C
Qn-D
Qn-E
Qn-F
Qn-G
Qn-H
00
I0-A
Mode 1S (1 Rate)
Mode 2S (2 Rates)
Mode 3S (3 Rates)
BBIN Data 1
BBIN Clk 2
BBIN Sync 2
I0-A
I0-B
I0-C
I0-D
I0-E
I0-F
I0-G
I0-H
Qn-A
Qn-B
Qn-C
Qn-D
Qn-E
Qn-F
Qn-G
Qn-H
00
I0-A
BBIN Data 2
‘n’ can be up to 47, ‘A’ is 2 MSBs, ‘B’ is next 2 bits, ‘C’ is next 2 bits, ... and ‘H’ is 2 LSBs
T0504-01
Figure 11. TX BB Formats
The TX formatter block includes a per-channel TX gain adjust via a 16-bit complex digital word which can be set
to have gain between –∞ and 9 dB.
Digital Down- and Upconverters (DDUCs)
The GC533x has four identical and independent DDUC blocks that can be configured as either DDC or DUC.
Each DDUC can support up to 12 channels with scalable bandwidth.
The only difference between the DUC and DDC configurations is the interpolate (DUC) versus decimate (DDC)
functions and the data path direction as shown in Figure 12. Both DDC and DUC are described in this section.
Note that each DDUC block must be configured statically as a DUC or DDC and cannot switch modes
dynamically in TDD applications.
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1–12 Channel DUC Block
NCO
From BB
Interface
Block
FIR
1´, 2´
Farrow
1–1024´
CIC
1–3´
X
To Mux and
Sum Block
Mixer
All 3 Blocks Interpolate
DUC Configuration
1–12 Channel DDC Block
NCO
To BB
Interface
Block
FIR
1´, 2´
Farrow
1–1024´
CIC
1–3´
X
From
Distributor
Block
Mixer
All 3 Blocks Decimate
DDC Configuration
B0448-01
Figure 12. DUC and DDC Functional Block Diagram
In combination with the follow-on mux and sum block, the DUC block interpolates, filters, mixes each carrier, and
combines multiple channels into one to four wideband, composite TX signal streams. Any input channel can be
mapped to any TX stream in the mux and sum block.
The DDC configuration accepts an RX stream from the distributor block and provides mixing, decimation filtering,
fractional resampling, and filtering to RX channels. The RX block outputs are mapped to the mixer CIC stream
via the distributor block.
Each DDUC block contains a finite impulse response (FIR) filter, a fractional resampler (Farrow filter), a
cascaded integrator-comb (CIC) filter, a complex mixer and NCO for channel placement in the composite stream,
and a programmable frequency hopper (see Figure 12).
The number of taps available in the FIR filter depends on various parameters such as the BBclk rate (derived
from DPDCLK) , input sample rate, interpolate and decimate settings, and number of channels. Different tap
values may be used for each channel (however, that reduces the number of filter taps available).
Note that the input sample rate is the input from the TX BB input formatter for the DUC configuration and the
input from the distributor block for DDC configuration. The number of taps for various wireless standards and
configurations is shown in Table 4.
The Farrow filter supports one real channel or 1–12 complex channels and can be configured for any resampling
ratio from 1 to 1024 with 32-bit resolution. A different delay value for each channel is supported. The Farrow filter
is used to resample different TX BB input sample rates to a common CFR and DPD sample rate, and it provides
95-dB rejection at ±0.25 output fS (sample rate), 83-dB rejection at ±0.375 output fS, and 56-dB rejection at ±0.4
output fS.
The CIC interpolates or decimates by a factor of 1, 2, or 3. If each DDUC must support more than eight carriers,
the CIC must interpolate/decimate by 3. If each DDUC must support between four and eight carriers, the CIC can
interpolate/decimate by 2 or 3. If each DDUC must support fewer than four carriers, the CIC can interpolate by 1,
2, or 3.
16
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The NCO contains a 48-bit frequency word and 48-bit accumulator, and operates at the DUC output sample rate.
The minimum resolution is the DUC output sample rate or DDC input sample rate divided by 248, or about 0.2
μHz for a 61.44-MSPS DUC output rate. The mixer and NCO can be used for frequency planning or fine
frequency control.
Per-channel phase can be adjusted in the mixer/NCO block with a 16-bit phase word, while per channel
fractional delay can be adjusted in the Farrow block.
Table 4. Number of FIR Filter Taps for Example Signal Types
Input
Sample
Rate
Filter Type
MHz
lte20_1
DUC Mode
Interp.
DDC Mode
Decim.
MSPS
Sym or
Un-Sym
1 or 2
1 or 2
245.76
30.72
S
1
lte20_2
245.76
30.72
S
lte10_2
245.76
15.36
S
lte10_3
245.76
15.36
lte10_4
245.76
15.36
lte5_4
245.76
lte5_8
245.76
wimax20_r3
BBclk
No. of
Channels
Max. Taps
1
1
159
1
1
2
79
1
1
2
159
S
1
1
3
99
S
1
1
4
79
7.68
S
1
1
4
159
7.68
S
1
1
8
79
246.4
44.8
S
1
2
3
59
wimax20_t3
246.4
22.4
S
2
1
3
39
wimax20_r2
246.4
44.8
S
1
2
2
99
wimax20_t2
246.4
22.4
S
2
1
2
79
wimax20_r1
246.4
44.8
S
1
2
1
219
wimax20_t1
246.4
22.4
S
2
1
1
199
wimax10_r2
246.4
22.4
S
1
2
2
219
wimax10_t2
246.4
11.2
S
2
1
2
199
wimax10_r3
246.4
22.4
S
1
2
3
139
wimax10_t3
246.4
11.2
S
2
1
3
119
wimax10_r4
246.4
22.4
S
1
2
4
99
wimax10_t4
246.4
11.2
S
2
1
4
79
wimax5_r4
246.4
11.2
S
1
2
4
219
wimax5_t4
246.4
5.6
S
2
1
4
199
wimax5_r8
246.4
11.2
S
1
2
8
99
wimax5_t8
246.4
5.6
S
2
1
8
79
wbcdma_r4
245.76
7.68
S
1
1
4
159
wbcdma_t4
245.76
3.84
S
2
1
4
319
wbcdma_r8
245.76
7.68
S
1
1
8
79
wbcdma_t8
245.76
3.84
S
2
1
8
159
cdma_r12
245.76
2.4576
S
1
1
12
99
cdma_t12
245.76
1.2288
U
2
1
12
100
tdscdma_r12
245.76
2.56
S
1
1
12
99
tdscdma_t12
245.76
1.28
S
2
1
12
199
gsm_12
243.8
0.5417
S
1
1
12
99
eedge_12
243.8
1.625
S
1
1
12
99
wideband_60MHz_r
250
75
S
1
1
1
59
wideband_60MHz_t
250
75
S
2
1
1
39
Name
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MUX and SUM (TX Direction)
The MUX and SUM block maps any channel from the DUC to any TX stream for subsequent per-stream
processing.
Crest Factor Reduction (CFR)
The CFR blocks include the CFR function and two interpolate-by-2 filters (referred to here as UC1 and UC2).
The two CFR blocks together can support 1, 2, or 4 TX streams. The CFR function selectively reduces the
peak-to-average ratio (PAR) of wideband digital signals provided in quadrature (I and Q) format, such as those
used in 3G and 4G wireless applications. For example, the CFR function can reduce the PAR of WCDMA Test
Model 1 signals to 5.7 dB, while still meeting all 3GPP requirements for ACLR, composite EVM, and peak code
domain error (PCDE).
The CFR blocks can be configured in eleven different modes, depending on the number of TX streams, the DPD
mode, and the signal sample rates. Relative to previous TI CFR products, the GC533x CFR has enhanced
features such as:
• Constant PAR mode
• Constant input-to-output power mode
• Dynamic PAR target levels for different portions of the time-domain signal
• Up to 25% less latency for certain configurations
• Enhanced CFR performance for narrowband signals
• Automatic (i.e., no host interaction required) CFR coefficient generation for frequency-hopping signals
The UC1 and UC2 blocks can be set to 1× or 2× interpolation and may be used to provide optimum selection of
signal oversampling ratio at CFR. UC1 may be positioned before or after the CFR function, while UC2 is always
at the output of CFR. Since UC2 has only a 40% bandwidth image rejection (90 dB) filter, it is only used if
preceded by UC1, which has an 80% bandwidth image-rejection (90 dB) filter.
Digital Predistortion (DPD)
The DPD blocks include the DPD function, TX equalization, and the envelope tracking (ET) function. The
GC533x supports two modes of operation, depending on signal bandwidth and desired DPD correction capability:
high-performance (HP) mode and high-bandwidth (HB) mode. For 5× DPD expansion bandwidth (fifth-order DPD
correction), the following signal bandwidths and number of streams can be supported.
High-performance DPD mode
1 TX stream at 62 {74} MHz
2 TX streams at 31 {37} MHz each
4 TX streams at 15.5 {18.5} MHz each
This mode provides more extensive nonlinear correction or longer DPD memory and is suitable for the
most-difficult and high-performance DPD requirements.
High-bandwidth DPD mode
1 TX stream at 62 {74} MHz
2 TX streams at 62 {74} MHz each
4 TX streams at 31 {37} MHz each
This mode provides excellent DPD correction for most DPD requirements.
The TX equalizer is a complex equalizer and is configurable from 17 to 34 taps, depending on the DPD mode of
operation. In HP modes, the number of taps may be up to 34. In HB modes, the number of taps may be up to 17.
Contact the TI factory for additional details.
The predistortion correction terms are computed by an external processor (e.g., TI TMS320C6748 DSP) based
on reference-input and PA-feedback data captured in the GC533x capture buffers. The external processor reads
the captured data buffers from the GC533x and writes back the newly computed DPD correction terms on a
continuous basis.
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DPD – Envelope Tracking (ET) Mode
The ET block provides a 10-, 12-, or 14-bit real digital word, at a rate up to 155 MSPS, that is proportional to the
peak envelope signal of the composite TX stream either before or after the DPD function. The ET block includes
fixed and fractional delay adjustments and a LUT to provide nonlinear shaping to the ET waveform. The GC533x
can provide one or two ET outputs along with the corresponding one or two TX signal stream outputs. The ET
outputs use one of the LVDS DAC ports and have two interface format modes:
a. One or two antenna streams. One antenna stream per port, with interleaved MSB half-word and LSB
half-word. The port can be configured as 7-, 6-, or 5-bit DDR data (see Table 14 and Figure 18), plus clock
(maximum clock rate of 155 MHz in this mode). In all three cases, the 16-bit internal data is rounded to the
specified 14, 12, or 10 bits. Format on the DDR data port for the three cases is:
14-bit: [13:7], then [6:0]
12-bit: [11:6], then [5:0]
10-bit: [9:5], then [4:0]
b. One antenna stream only. One antenna stream per port. The port can be configured as 14-, 12-, or 10-bit
SDR data (see Figure 18), plus clock (maximum clock rate of 155 MHz in this mode). In all three cases, the
16-bit internal data is rounded to the specified 14, 12, or 10 bits.
Note that clock out may have a few hundred ps of jitter and is not suitable for directly driving the ET modulator
DAC. The clock for the ET modulator DAC should come directly from a TI CDC clock chip, which is already on
the board to provide clock sources.
TX IF Sub-Chip
The TX IF sub-chip includes a bulk upconverter (BUC), four IF mixer/NCO blocks, and TX stream MUX and
SUM.
The BUC block has interpolations of 1×, 1.5×, 2×, 3×, and 4×. In the DPD high-band width mode, the 2×
interpolation from the BUC is routed to the DPD input. In the high-bandwidth mode, BUC interpolation is not used
after DPD. In the DPD high-performance mode, BUC interpolation is dependent on the configuration.
There are four parallel NCO/MIX blocks to allow frequency translation of each composite TX stream. The NCO is
48 bits and is referenced to the TX output rate. The NCO/MIX block can be used in either HP or HB modes;
however, using the mixer reduces the DPD expansion bandwidth by the amount of frequency translation.
The TX stream MUX and SUM block allows summing of TX streams to create composite TX streams.
TX DAC Formatter
The DAC output consists of two 20-pair LVDS blocks that can be configured by the DAC formatter block for
several TI DACs and system configurations. The formatter can support up to 8 DACs for 4 TX streams in
complex mode. The DAC formatter block supports the TI DAC5682, DAC328x, and DAC348x families. Table 5
illustrates the pin connections the different DAC and envelope [ET] modulator types.
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Table 5. GC533x DAC Interface Pin Map
GC533x
328x (ET)
3482 Byte
5682
3484
3482 Word
TXA0
P1-d7
P1-d7
P1-sync
P1-sync
P1-sync
TXA1
P1-d6
P1-d6
P1-d15
P1-d15
P1-d15
TXA2
P1-d5
P1-d5
P1-d14
P1-d14
P1-d14
TXA3
P1-d4
P1-d4
P1-d13
P1-d13
P1-d13
TXA4
P1-dataclk
P1-dataclk
P1-d12
P1-d12
P1-d12
TXA5
P1-frame
P1-frame
P1-d11
P1-d11
P1-d11
TXA6
P1-d3
P1-d3
P1-d10
P1-d10
P1-d10
TXA7
P1-d2
P1-d2
P1-d9
P1-d9
P1-d9
TXA8
P1-d1
P1-d1
P1-d8
P1-d8
P1-d8
TXA9
P1-d0
P1-d0
P1-dataclk
P1-dataclk
P1-dataclk
TXA10
P2-d7
P2-d7
NA
P1-frame
NA
TXA11
P2-d6
P2-d6
P1-d7
P1-d7
P1-d7
TXA12
P2-d5
P2-d5
P1-d6
P1-d6
P1-d6
TXA13
P2-d4
P2-d4
P1-d5
P1-d5
P1-d5
TXA14
P2-dataclk
P2-dataclk
P1-d4
P1-d4
P1-d4
TXA15
P2-frame
P2-frame
P1-d3
P1-d3
P1-d3
TXA16
P2-d3
P2-d3
P1-d2
P1-d2
P1-d2
TXA17
P2-d2
P2-d2
P1-d1
P1-d1
P1-d1
TXA18
P2-d1
P2-d1
P1-d0
P1-d0
P1-d0
TXA19
P2-d0
P2-d0
NA
P1-parity
P1-parity
TXB0
P3-d7
P3-d7
P2- sync
P2-sync
P2-sync
TXB1
P3-d6
P3-d6
P2-d15
P2-d15
P2-d15
TXB2
P3-d5
P3-d5
P2-d14
P2-d14
P2-d14
TXB3
P3-d4
P3-d4
P2-d13
P2-d13
P2-d13
TXB4
P3-dataclk
P3-dataclk
P2-d12
P2-d12
P2-d12
TXB5
P3-frame
P3-frame
P2-d11
P2-d11
P2-d11
TXB6
P3-d3
P3-d3
P2-d10
P2-d10
P2-d10
TXB7
P3-d2
P3-d2
P2-d9
P2-d9
P2-d9
TXB8
P3-d1
P3-d1
P2-d8
P2-d8
P2-d8
TXB9
P3-d0
P3-d0
P2-dataclk
P2-dataclk
P2-dataclk
TXB10
P4-d7
P4-d7
NA
P2-frame
NA
TXB11
P4-d6
P4-d6
P2-d7
P2-d7
P2-d7
TXB12
P4-d5
P4-d5
P2-d6
P2-d6
P2-d6
TXB13
P4-d4
P4-d4
P2-d5
P2-d5
P2-d5
TXB14
P4-dataclk
P4-dataclk
P2-d4
P2-d4
P2-d4
TXB15
P4-frame
P4-frame
P2-d3
P2-d3
P2-d3
TXB16
P4-d3
P4-d3
P2-d2
P2-d2
P2-d2
TXB17
P4-d2
P4-d2
P2-d1
P2-d1
P2-d1
TXB18
P4-d1
P4-d1
P2-d0
P2-d0
P2-d0
TXB19
P4-d0
P4-d0
NA
P2-parity
P2-parity
Note: P1, P2, P3, and P4 are used to identify a specific DAC port. Different ports have different timing.
20
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RX ADC Formatter
There are three ADC input ports: two 15-pair LVDS ports (referred to as ports A and B) and one 8-pair LVDS
port (referred to as port C and typically used for the DPD feedback path). Depending on the ADCs selected,
these three ports can accommodate up to 17 ADCs (e.g., using two octals and a single). The formatter block can
route any port to either the capture buffer block or the RX signal processing blocks. The pin connections for the
ADCs are shown in Table 6.
The GC533x works seamlessly with the following TI ADCs.
Single: 5400, 12-bit, 1 GSPS, may need special routing on the PCB.
5463, 12-bit, 500 MSPS, may need clock-to-data-skew special routing on the PCB.
54RF63, 12-bit, 550 MSPS, may need clock-to-data-skew special routing on the PCB.
5474, 14-bit, 400 MSPS, may need clock clock-to-data-skew special routing on the PCB.
5493, 16-bit, 130 MSPS
548x, 16-bit, 80-200 MSPS
612x, 12-bit, 65–250 MSPS
614x, 14-bit, 65-250 MSPS
58B18, 11-bit, 200 MSPS
414x, 14-bit, 160–250 MSPS
412x, 12-bit, 160–250 MSPS
552x, 12-bit, 170–210 MSPS
554x, 14-bit, 170–210 MSPS
5517, 11-bit, 200 MSPS
Dual:
62c15, 11-bit, 125 MSPS
62c17, 11-bit, 200 MSPS
58c28, 11-bit, 200 MSPS
62p4x, 14-bit, 65-250 MSPS
62p2x, 12-bit, 65-250 MSPS
624x, 14-bit, 65-125 MSPS
622x, 12-bit, 65-125 MSPS
Quad:
642x, 12-bit, 65–125 MSPS
644x, 14-bit, 65–125 MSPS
Octal:
527x, 12-bit, 65 MSPS
528x, 12-bit, 65 MSPS
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Table 6. GC533x ADC Interface Pin Map
58c48 42x9
64p4x
62p4x
62c15
5463 5444
5474
5400L
5400R
642x 644x
0
0
0
[12] (1)
syncout
[istrobe]
RXA1
2
2
1
11
0
RXA2
4
4
2
10
1
d1
b1
RXA3
6
0
6
3
9
2
d0
b0
RXA4
8
2
8
4
8
3
c1
RXA5
10
4
10
5
7
4
c0
GC533x
Pin Name
58b18 5517
4149 61B49
5547
RXA0
(1)
548x 6145
527x 528x
Two 624x
f
c0
a1
RXA6
12
6
12
6
6
5
frame
c1
a0
RXA7
clk
clk
clk
7
clk
clk
clk
clk
clk
RXA8
[14]
8
0
8
5
6
b1
c2
RXA9
10
2
9
4
7
b0
c3
b1
RXA10
12
4
10
3
8
a1
c4
b0
RXA11
14
6
11
2
9
a0
c5
f
RXA12
8
12
1
10
c6
a1
RXA13
10
13
0
11
c7
a0
12
clk
syncout
[12]
fr
clk
RXA14
[istrobe]
[istrobe]
RXB0
0
0
0
[12]
syncout
RXB1
2
2
1
11
0
RXB2
4
4
2
10
1
RXB3
6
0
6
3
9
2
RXB4
8
2
8
4
8
3
RXB5
10
4
10
5
7
4
RXB6
12
6
12
6
6
5
RXB7
clk
clk
clk
7
clk
clk
RXB8
[14]
8
0
8
5
6
RXB9
10
2
9
4
7
RXB10
12
4
10
3
8
RXB11
14
6
11
2
9
RXB12
8
12
1
10
RXB13
10
13
0
11
12
clk
syncout
[12]
RXB14
[istrobe]
RXC0
0
RXC1
2
RXC2
4
RXC3
6
RXC4
8
RXC5
10
RXC6
12
RXC7
clk
[istrobe]
[ ] indicates assignment if pins available
Feedback Processing
The feedback path is input to RXC as a real ADC. This is captured in the capture buffer and sent to the DSP. In
cases where a higher-rate real ADC (>250 Msps) or a complex feedback path is desired, for better feedback
performance, one of the RX ADC inputs can be used for the feedback path, and one RX ADC input is used for
the RX path. Note: both RX downconverters can still be used for the RX path, or one can be used for feedback.
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The widest-band feedback is seen directly from the ADC interface to the capture buffer. Further RX processing to
get the complex data to the capture buffer requires that the complex rate is one-half the DPD clock rate or lower.
RX Sub-Chips
Each of two RX sub-chips consists of the following blocks (each block may be optionally bypassed), which
operate on a per-stream basis:
• DC offset cancellation
• Front-end automatic gain control (feAGC)
• Real-to-Complex (R2C) conversion
• Switch for replicating or moving streams across the four paths (per sub-chip)
• IF NCO for complex mixing (frequency translation)
• Bulk downconverter (BDC)
• Equalizer
• IQ imbalance correction
DC offset cancellation
The dc offset canceller can be programmed to integrate a number of input samples automatically, divide by a
power of 2, and subtract the mean offset or a programmed offset from the input. The input can be real or
complex. Each input ADC has a separate cancellation for each RX block channel.
Front-end AGC
The feAGC block is used to control the RX ADC input level by controlling an external DVGA.
The feAGC has multiple channels in each RX block:
• 1 real stream up to 4 × DPD clock rate (only use one block)
• 2 real (using both blocks) or 1 complex stream (only use one block) up to 2 × DPD clock rate each
• 4 real or 2 complex streams up to DPD clock rate each (uses both blocks)
• 8 real or 4 complex streams up to 1/2 DPD clock rate each (uses both blocks)
The feAGC has both threshold comparison and an integrated power measurement. The feAGC has an error
accumulation. The error accumulation can be mapped to a specific ADC desired operating point. The integral
controller outputs the DVGA value to control the ADC input. DVGA controls are mapped to the specific DVGA
outputs, supporting multiple DVGA types. Multipliers in the data path can be used to compensate for external
DVGA gain changes (from the feAGC output control word). A delay block aligns the gain value applied to the
internal multiplier with the point in time on the data samples where the external gain change was applied. Use of
this multiplier minimizes gain steps that would cause transients in the downstream digital filters and allows
relative power measurements on the digital signals.
The AGC operation may be suspended during certain conditions. The internal controlled-delay AGC update and
special clock gating can be used to suspend the AGC operation.
The control word outputs from the feAGC blocks are applied to external DVGA parts via the DVGA pins. There
are 16 DVGA pins (3.3-V CMOS) which may be individually configured as DVGA output signals or GPIO (input or
output) signals. When used as DVGA control signals, there are two modes:
• Transparent mode – parallel output words are connected directly to DVGAs that are being used in a mode
without a clock or latch signal to clock-in the gain word. This is the minimum latency mode. There can be two
ports of 8 bits each, three ports of 5 bits each, four ports of 4 bits each, or five ports of 3 bits each.
• Clocked mode – eight latch enable (LE) signals and one 8-bit output word. This mode allows up to eight
control signals, up to 8 bits each, but with increased latency. The LE signal may be a positive or negative
pulse, with programmable width.
R2C
In the real-to-complex conversion block, real signal inputs are up- or downconverted by fS/4, filtered to isolate the
selected sideband, and decimated by a factor of 2. Real-to-complex conversion is bypassed for complex inputs.
The rejection of the R2C decimation filter is:
• For 90% bandwidth signal, –68 dB, stop band
• For 80% bandwidth signal, –106 dB, stop band
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Switch
Any of the up to eight complex RX antenna/signal inputs across both sub-chips may be switched to one or more
of the up to 4 output streams of each sub-chip.
IF NCO
The NCO/mixer block generates in-phase and quadrature sinusoidal signals (cos/sin) and mixes them with the
switched antenna streams to frequency-translate the RX signals. The NCO contains a 48-bit frequency word and
48-bit accumulator.
BDC
The BDC supports the following modes and sample rates at its input (across both sub-chips):
• Single – 4 × DPD clock rate real, 2× DPD clock rate complex
• Dual – 2 × DPD clock rate real, DPD clock rate complex
• Quad – DPD clock rate real, 1/2 DPD clock rate complex
• Octal – 1/2 DPD clock rate real
Total decimation factors may be 1, 2, 4, 8, or 16. The decimation filtering is achieved with the cascade of the
real-to-complex filter (R2C), a fixed filter F1, and a fixed filter F2. The rejection of the F1 and F2 filters is:
• Filter F1 (decimate by 1 or 2)
– If used, always followed by filter F2, so relaxed requirements
– 45% bandwidth, –107 dB stopband
• Filter F2
– Recirculated 1–3 times to provide 2, 4, or 8× decimation factor
– 90% bandwidth, –75 dB, stop band
– 80% bandwidth, –106 dB, stop band
Equalizer
The receive equalizer is full-complex 16-tap filter that performs the following signal-processing functions:
• Programmable spectral inversion at the input
• Equalization of analog signal paths
• Channel equalization for repeater applications
• Gain/phase/fractional delay adjust (MIMO/smart antenna support)
• Fixed dc offset compensation at the output
Independent complex coefficients for real and imaginary signal data allow full flexibility for independent
equalization of the direct- and cross-IQ signal components, as well as frequency-dependent IQ gain and phase
imbalance compensation. The programmable 16-bit coefficient sets (i.e., Cii, Cqq, Ciq and Cqi, for each tap) can be
updated on the fly.
IQ imbalance correction
Automatic correction of IQ imbalance is provided with a 1-tap blind adaptive algorithm. The correction coefficients
also may be programmed to fixed values. This block supports programmable integration intervals and flexible
gating of loop operation.
RX Distributor
The outputs from the RX sub-chips are routed to the RX distributor block, which enables arbitrary assignment of
RX streams to DDC channels and blocks.
RX Baseband Output Formatter
The RX baseband (BB) output formatter block accepts data from the DDC and formats the data for output on the
BB LVDS pins. A back-end AGC (beAGC) function is included that optionally adjusts the gain of each channel
and provides multiple format options. There are 12 unidirectional LVDS pairs for the RX BB interface.
24
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Back-end AGC
The beAGC function is available for receive channels from DDUC3 and DDUC2 (DDUC1 and DDUC0 may also
be used for receive—with the formats as described following—but without the beAGC function). When the
floating-point format is selected (described following), the beAGC is not used. For the fixed-point formats, the
beAGC may be on or off. There are separate beAGC blocks associated with DDUC3 and DDUC2, and each
block can process up to 12 channels. Within a block, there are two sets of control parameters. This provides
support for two different signal types sharing the same DDUC block. Each channel may have a
programmable-gain starting point or a fixed gain, and there is a per-channel flexible gating signal to control
freeze/operate intervals for TDD signal types. The beAGC has approximately a 100 dB dynamic range. The
beAGC algorithm adjusts the gain to drive the median magnitude of gain-loop output data to a target threshold
value. There are four step-sizes used (two for above and two for below the threshold), depending on distance
from the threshold value.
Output formatter
There are three operational modes for the RX BB output formatter: byte mode (B, 9 bits), nibble mode (N, 4 bits),
and serial mode (S, 2 bits). The nibble and serial modes allow multiple BB output rates and the use of fewer pins
on the interface. The GC533x can provide up to three different BB output data rates. Table 7 and Table 8
summarize the different modes and pin assignments for the byte, nibble, and serial modes. As can be seen in
Table 8, there are two data formats supported:
• Floating point (indicated with an F in the mode label; 14- or 16-bit mantissa, 4-bit exponent)
• Fixed point without gain word (16- or 18-bit options)
In Table 8, BBOUT[X] is the BBOUT differential pair (assumed positive and negative connections), and BB0,
BB1, and BB2 represent three different RX differential baseband input signals that can be at arbitrary rates.
Figure 13 shows the BB output formats. The maximum-data-rate configurations have the DDR clock out
transitioning synchronously with the data (referred to as DDR Mode 0 in the table). At half the maximum possible
data rate (referred to as DDR Mode 1 in the table) and a quarter of the maximum possible data rate (referred to
as DDR Mode 2 in the table), the DDR clock out transitions in the middle of the data-steady time .
Table 7. RX BB Formatter Modes
MODE
Description
Total Number of Interface
Pins
Maximum Complex Interface Rate per Channel
N is the number of channels
1B
1 interface rate (up to 18 bits)
11 = 9 data + 1 clk + 1 sync
(Clk4/4)/N/2; maximum 125 MSPS total (for all channels)
1BF
1 interface rate (up to 16 bits) + exponent (4
bits)
10 = 8 data + 1 clk + 1 sync
(Clk4/4)/N/2; maximum 125 MSPS total (for all channels)
1N
1 interface rate (16 bits)
6 = 4 data + 1 clk + 1 sync
(Clk4/8)/N; maximum 96.15 (Nibble0), 125 (Nibble1) MSPS total
1NF
1 interface rate (14 bits) + exponent (4 bits)
6 = 4 data + 1 clk + 1 sync
(Clk4/8)/N; maximum 96.15 (Nibble0), 125 (Nibble1) MSPS total
1S
1 interface rate (16 bits)
4 = 2 data + 1 clk + 1 sync
(Clk4/16)/N; maximum 48.07 MSPS total
1SF
1 interface rate (14 bits) + exponent (4 bits)
4 = 2 data + 1 clk + 1 sync
(Clk4/16)/N; maximum 48.07 MSPS total
2N
2 interface rates (16 bits)
12 = 4 data + 1 clk + 1 sync +
4 data + 1 clk + 1 sync
(Clk4/8)/N; maximum 221.15 MSPS total
2NF
2 interface rates (14 bits) + exponent (4 bits)
12 = 4 data + 1 clk + 1 sync +
4 data + 1 clk + 1 sync
(Clk4/8)/N; maximum 221.15 MSPS total
2S
2 interface rates (16 bits)
8 = 2 data + 1 clk + 1 sync +
2 data + 1 clk + 1 sync
(Clk4/16)/N; maximum 96.15 MSPS total
2SF
2 interface rates (14 bits)+ exponent (4 bits)
8 = 2 data + 1 clk + 1 sync +
2 data + 1 clk + 1 sync
(Clk4/16)/N; maximum 96.15 MSPS total
3S
3 interface rates (16 bits)
12 = 2 data + 1 clk + 1 sync +
2 data + 1 clk + 1 sync +
2 data + 1 clk + 1 sync
(Clk4/16)/N; maximum 144.23 MSPS total
3SF
3 interface rates (14 bits)+ exponent (4 bits)
12 = 2 data + 1 clk + 1 sync +
2 data + 1 clk + 1 sync +
2 data + 1 clk + 1sync
(Clk4/16)/N; maximum 144.23 MSPS total
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Table 8. RX BB Pin Assignments
LVDS Pair BBI[11:0]
Byte Mode
Nibble Mode
Serial Mode
BBOUT[0] pos. and neg.
BB0_DATA_0
BB0_DATA_0
BB0_DATA_0
BBOUT[1] pos. and neg.
BB0_DATA_1
BB0_DATA_1
BB0_DATA_1
BBOUT[2] pos. and neg.
BB0_DATA_2
BB0_SYNC
BB0_SYNC
BBOUT[3] pos. and neg.
Spare
BB0_CLOCK
BB0_CLOCK
BBOUT[4] pos. and neg.
BB0_DATA_3
BB0_DATA_2
BB1_DATA_0
BBOUT[5] pos. and neg.
BB0_DATA_4
BB0_DATA_3
BB1_DATA_1
BBOUT[6] pos. and neg.
BB0_SYNC
BB1_SYNC
BB1_SYNC
BBOUT[7] pos. and neg.
BB0_CLOCK
BB1_CLOCK
BB1_CLOCK
BBOUT[8] pos. and neg.
BB0_DATA_5
BB1_DATA_0
BB2_DATA_0
BBOUT[9] pos. and neg.
BB0_DATA_6
BB1_DATA_1
BB2_DATA_1
BBOUT[10] pos. and neg.
BB0_DATA_7
BB1_DATA_2
BB2_SYNC
BBOUT[11] pos. and neg.
BB0_DATA_8
BB1_DATA_3
BB2_CLOCK
Number of BBdata streams
1
2
3
Number of DDR clocks to transfer 1 complex sample
2
4
8
BBOUT Clk 0
(if DDR Mode 0)
BBOUT Clk 0
(if DDR Mode 1 or 2)
BBOUT Sync 0
I0-O
I0-E
Q0-O
Q0-E
I1-O
I1-E
Q1-O
Q1-E
In-O
In-E
Qn-O
Qn-E
I0-O
I0-E
Q0-O
Q0-E
BBOUT Data 0
Mode 1B
18 bit I/Q Data
9I, 9I, 9Q, 9Q
Mode 1BF
16 bit I/Q Data + 4 bits gain
8I +1G, 8I + 1G, 8Q + 1G, 8Q + 1G
‘n’ can be up to 47, ‘O’ is 8 (or 9) odd numbered bits (1, 3, 5, ...), ‘E’ is 8 (or 9) even numbered bits (0, 2, 4, ...), with 0 being the LSB
BBOUT Clk 0
(if DDR Mode 0)
BBOUT Clk 0
(if DDR Mode 1 or 2)
BBOUT Sync 0
I0-A
I0-B
I0-C
I0-D
Q0-A
Q0-B
Q0-C
Q0-D
In-A
In-B
In-C
In-D
Qn-A
Qn-B
Qn-C
Qn-D
BBOUT Data 0
BBOUT Clk 1
(if DDR Mode 0)
BBOUT Clk 1
(if DDR Mode 1 or 2)
Modes 1N, 2N
16 bit I/Q Data
4I, 4I, 4I, 4I, 4Q, 4Q, 4Q, 4Q
Modes 1NF, 2NF
14 bit I/Q Data + 4 bits gain
4I, 4I, 4I, 2I +2Q, 4Q, 4Q, 4Q, 4G
BBOUT Sync 1
I0-A
I0-B
I0-C
I0-D
Q0-A
Q0-B
Q0-C
Q0-D
In-A
In-B
In-C
In-D
Qn-A
Qn-B
Qn-C
Qn-D
BBOUT Data 1
‘n’ can be up to 47, ‘A’ is 4 MSBs, ‘B’ is next 4 bits, ‘C’ is next 4 bits and ‘D’ is 4 LSBs
BBOUT ClkOUT 0
(if DDR Mode 0)
BBOUT Clk 0
(if DDR Mode 1 or 2)
BBOUT Sync 0
I0-A
I0-B
I0-C
I0-D
I0-E
I0-F
I0-G
I0-H
Qn-A
Qn-B
Qn-C
Qn-D
Qn-E
Qn-F
Qn-G
Qn-H
BBOUT Data 0
BBOUT Clk 1
(if DDR Mode 0)
BBOUT Clk 1
(if DDR Mode 1 or 2)
BBOUT Sync 1
I0-A
I0-B
I0-C
I0-D
I0-E
I0-F
I0-G
I0-H
Qn-A
Qn-B
Qn-C
Qn-D
Qn-E
Qn-F
Qn-G
Qn-H
BBOUT Data 1
Modes 1S, 2S, 3S
16 bit I/Q Data
4I, 4I, 4I, 4I, 4Q, 4Q, 4Q, 4Q
Modes 1SF, 2SF, 3SF
14 bit I/Q Data + 4 bits gain
4I, 4I, 4I, 2I +2Q, 4Q, 4Q, 4Q, 4G
BBOUT Clk 2
(if DDR Mode 0)
BBOUT Clk 2
(if DDR Mode 1 or 2)
BBOUT Sync 2
I0-A
I0-B
I0-C
I0-D
I0-E
I0-F
I0-G
I0-H
Qn-A
Qn-B
Qn-C
Qn-D
Qn-E
Qn-F
Qn-G
Qn-H
BBOUT Data 2
‘n’ can be up to 47, ‘A’ is 2 MSBs, ‘B’ is next 2 bits, ‘C’ is next 2 bits, ... and ‘H’ is 2 LSBs
T0505-01
Figure 13. RX BB Formats
26
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Capture Buffers
The GC533x has two capture buffers, each 4096 complex words (18-bits I, 18-bits Q) deep, which are
periodically read by the external coefficient update controller (DSP) in order to optimize the DPD coefficients. The
capture buffers can be configured to sample data signals at the following points in the GC533x:
● DPD HP mode input
(Referred to as node A)
● DPD HP mode output
(Node B)
● DPD HB mode input
(Node C)
● DPD HB mode output
(Node D)
● RX AB input
(Node E)
● RX path 0/1 output
(Node F)
● RX C (feedback) input
(Node G)
● Testbus
The capture buffers can be triggered via an external sync signal, through a software trigger, or when the
monitored signal exceeds the user-configurable thresholds. The capture buffers can be programmed to monitor
the signal statistics continuously and only capture data when certain requirements are met, as well as to
generate an interrupt when a qualified buffer is captured. This helps in selecting an optimum set of data for the
DSP to use in optimizing the DPD coefficients. The capture buffers can be read by the DSP via the MPU
interface.
The capture buffers also allow synchronized multi-chip data capture. For a multiple antenna system that uses
more than one GC533x, a feedback signal to use in adapting DPD coefficients in multiple GC533x chips can be
connected to just one of the GC533x chips. The SYNCOUT signal can be used to daisy-chain (e.g., connecting
to SYNCA on the next chip) across the GC533x chips in the system. The SYNCOUT signal indicates the end of
the data capture and can be used as a capture trigger in all chips.
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, an 8-bit address bus, and WEB, OEB, CEB,
and EMIFENA control signals. The interface supports the TI ‘C6748 as an EMIF asynchronous interface. The
MPU interface has two address spaces: a paged address space and an auto-increment address space.
To enable the EMIF interface, pin EMIFENA must be set to logic high.
In an MPU write cycle, a GC533x internal MPUCLK signal is generated by NORing CEB and WEB. The
MPUCLK signal goes high when both CEB and WEB are asserted and goes low as soon as either CEB or WEB
is de-asserted. The MPU data is latched on the rising edge of the MPUCLK signal. For the auto-increment
address spaces, the auto-increment address increments on the falling edge of the MPUCLK signal.
In an MPU read cycle, a GC533x internal MPUCLK signal is generated by NORing CEB and OEB. The MPUCLK
signal goes high when both CEB and OEB are asserted and goes low as soon as either CEB or OEB is
de-asserted. The MPU readback data is available soon after the rising edge of the MPUCLK signal. For the
auto-increment address spaces, the auto-increment address increments on the failing edge of the MPUCLK
signal.
Figure 14 shows the MPU interface timing diagram. The timing specifications are provided in Table 26 and
Table 27.
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Write Cycle
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Read Cycle
CEB
Addr
OEB
WEB
Data
T0506-01
Figure 14. MPU Interface Format
Serial Peripheral Interface (SPI)
The MPU and SPI interfaces can be only enabled one at a time. EMIFENA must be set to logic low to enable the
SPI interface. A three- or four-wire SPI interface is supported in the GC533x. It consists of SPIDENB, SPICLK ,
SPIDIO, and SPIDO-(SPARE) (output in four-wire mode) signals. See Table 25 and Figure 25.
JTAG Interface
The GC533x includes a five-pin JTAG interface that supports boundary scan for all CMOS pads in the chip,
aside from the TESTMOD pin. The BBIN, BBOUT, RX, TX, and SYNC pins are all LVDS and do not get JTAG
boundary scan. IMPORTANT NOTE: if not using JTAG, the TRSTB signal should be grounded (or pulled to
ground through R ≤ 1 kΩ); otherwise, the JTAG port may take control of the pins. See Table 24 and Figure 24.
A BSDL file is available on the GC533x Web page.
Input and Output Syncs
The GC533x features two LVDS input syncs (SYNCA and SYNCB) and one LVDS output (SYNCOUT)
user-programmable sync. These are typically used as trigger/synchronization mechanisms to activate features
within the device. The input syncs can be used to trigger events such as:
• Power measurements
• DUC channel delay, mixer phase and dither
• Initializing/loading filter coefficients
• Capturing and sourcing of data in the capture buffers
• Controlling gating intervals for AGC and other adaptive loops
• Frequency NCO changes, or hopping synchronization
The SYNCA signal is used for device startup. The SYNCB signal can be used for shared feedback
synchronization between multiple GC533x devices. The sync signal is active-high. The width (number of positive
edges of the DPD clock) of the sync signal depends on the configuration. See the GC533x sync and MPU
application note to determine the proper sync duration. A typical sync-pulse duration is four DPD clocks. The
sync must be periodic, and usually starts at the beginning of the TX frame.
The output sync can be programmed to reflect triggering of specific events within the GC533x, and is primarily
used to output the capture-buffer sync out signal.
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Programmable Power Meters
Interval-Based Power Meter
There are three interval-based power meters which compute magnitude-squared sample values during
programmable time intervals and provide the following results:
• Integrated magnitude-squared power
• Peak power
• Number of magnitude-squared values above a first threshold
• Number of magnitude-squared values above a second threshold
An interrupt bit is set when new measurement results are available. For its input, each power meter can
independently select from the same set of internal node sources as the capture buffers.
Running-Average Power Meter for PA Protection
The running-average power meter monitors up to four signal streams on a single node, which is selectable from
the same set of internal sources as the capture buffers. For each signal stream, it measures running-average
power and counts instantaneous power values above a threshold (referred to as peaks). It can be used in
conjunction with hardware alarms for monitoring power levels for PA protection.
The running-average power meter has the following features:
• Running average mode, with programmable forgetting factor exponent, u (0 < u < 15)
AAA y(k+1) = (1 – 2-u) × y(k) + 2-u × |x(k)|2,
AAA where x(k) is the signal sample and y(k) is the power meter output.
AAA Typically, one must set u = 11 to get 0.5-dB accuracy, u = 14 to get 0.1-dB accuracy.
• Peak count mode: counts the number of power values, |x(k)|2, above a threshold in a specified number of
samples (window). The number of power values, threshold, and window are all programmable.
• Flexible gating of the operation interval
Alarms
The output, y(k), from the running-average power meter can be compared on an ongoing basis to programmable
high and low thresholds (always positive). There are two alarms, alarm0 and alarm1. Each alarm is triggered (if it
is enabled) based on the programmed mode:
(0) Disabled
(1) Average power alarm. The alarm is triggered based on the following conditions:
If alarm polarity = 0 (see the alm_polarity register), y(k) > high_threshold
If alarm polarity = 1, y(k) < low_threshold
If alarm polarity = 2, y(k) > high_threshold or y(k) < low_threshold
(2) Peak power alarm. The alarm is triggered based on the following conditions:
If the count of power values |x(k)|2 > peak_threshold exceeds the programmed number of
samples, peak_samples, in a programmed window, peak_window
(3) The alarm is triggered if either (1) or (2) occurs.
Alarm checks are computed on a per-antenna-stream basis. Each antenna stream y(k) result is compared to
per-stream programmable thresholds.
Once an alarm has been triggered, the output INTERRPT pin is asserted and the appropriate (alarm0 or alarm1)
alarm interrupt bit is set and, for alarm1, a programmable action takes place. The programmable action is the
same for all antenna streams, but the alarm triggering is independent for each antenna stream.
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Programmable trigger actions for alarm1:
(0) No action
(1) Reduce gain of DPD output by programmable scale factor (programmed with
stream[n].gain_reduce), only if alarm caused by y(k) > high_threshold and alm_polarit = 0 or 2.
The gain reduction is applied at the CFR input. A control signal from the capture buffer block is
used to select the programmed gain value for the multiplier at the CFR input. When the host
resets this alarm by writing to the appropriate register, the control signal returns to 0 (state that is
not selecting the programmed gain value).
GENERAL SPECIFICATIONS
General Electrical Characteristics
This section describes the electrical characteristics for the CMOS interfaces (DVGA, MPU, JTAG, SPI,
TESTMOD, RESETB and INTERRPT) and LVDS interfaces (BBIN, BBOUT, TXA, TXB, RXA, RXB, RXC, SYNC,
DPDCLK) over recommended operating conditions (unless otherwise noted).
Table 9. General Electrical Characteristics, CMOS Interface
PARAMETER
TEST CONDITIONS
VIL
Voltage input low
See
(1)
VIH
Voltage input high
See
(1)
MIN NOM
MAX
UNIT
0.8
V
2
VDDSHV
V
0.5
V
VDDSHV
V
(1)
VOL
Voltage output low
IOL = 2 mA
VOH
Voltage output high
IOH = –2 mA) (1)
2.4
|IPU|
Pullup current
VIN = 0 V (1)
30
100
250
µA
|IPD|
Pulldown current
VIN = VDDSHV (1)
30
100
250
µA
|IIN|
Leakage current
VIN = 0 or VDDSHV (1) (2)
20
µA
(1)
(2)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
For inputs with no pullup or pulldown, inputs with pullup and VIN = VDDSHV, inputs with pulldown and VIN = 0, and bidirectionals in input
mode in either state.
Table 10. General Electrical Characteristics, LVDS Interfaces
PARAMETER
Input common mode voltage (VP – VN)/2
VICM
TEST CONDITIONS
MIN
See
(1)
700
150
NOM
MAX
UNIT
1500
mV
700
mV
|VP – VN|
Input differential voltage
See
(1)
RIN
Input differential impedance
See
(1)
80
92
120
Ω
VCOM
Output common-mode voltage
See
(2)
1125
1200
1275
mV
VOD
Ouput differential voltage
See
(1)
250
500
mV
(1)
(2)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Characteristics are determined by design.
General Switching Characteristics
The baseband interface TX has a single DDR interface input mode. The customer logic and trace routing must
meet the listed tsu and th input timing.
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Table 11. General Switching Characteristics, TX BB LVDS Input
PARAMETER
TEST CONDITIONS
MIN NOM MAX
UNIT
BASEBAND INTERFACE DDR LVDS
fCLK(BB-Serial)
fCLK(BB-Nibble)
384
Baseband input clock frequency
See
(1)
500(Nibble0)
384(Nibble1)
fCLK(BB-Byte)
MHz
384
fCLK(RXA)
Baseband input clock frequency, using RXA
See
(1)
tsu(BBS0)
BBIN3 Clk, BBIN1:0 Data, BBIN2 Sync
See
(1) (2)
250
ps
thi(BBS0)
BBIN3 Clk, BBIN1:0 Data, BBIN2 Sync
See
(1) (2)
200
ps
250
MHz
tsu(BBS1)
BBIN7 Clk, BBIN5:4 Data, BBIN6 Sync
See
(1) (2)
210
ps
thi(BBS1)
BBIN7 Clk, BBIN5:4 Data, BBIN6 Sync
See
(1) (2)
250
ps
tsu(BBS2)
BBIN11 Clk, BBIN9:8 Data, BBIN10 Sync
See
(1) (2)
240
ps
thi(BBS2)
BBIN11 Clk, BBIN9:8 Data, BBIN10 Sync
See
(1) (2)
190
ps
tsu(BBN0)
BBIN3 Clk, BBIN5,4,1,0 Data, BBIN2 Sync
See
(1) (2)
250
ps
th(BBN0)
BBIN3 Clk, BBIN5,4,1,0 Data, BBIN2 Sync
See
(1) (2)
220
ps
tsu(BBN1)
BBIN7 Clk, BBIN11:8 Data, BBIN6 Sync
See
(1) (2)
250
ps
th(BBN1)
BBIN7 Clk, BBIN11:8 Data, BBIN6 Sync
See
(1) (2)
220
ps
tsu(BB)
BBIN7 Clk, BBIN11:8,5:4,2:0 Data, BBIN6 Sync
See
(1) (2)
280
ps
th(BB)
BBIN7 Clk, BBIN11:8,5:4,2:0 Data, BBIN6 Sync
See
(1) (2)
250
ps
(1)
(2)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Setup and hold times are measured from differential data crossing zero to differential clock crossing zero.
BBIN Clk
BBIN Data, BBIN Sync
tsu
th
th
tsu
T0507-01
Figure 15. TX Baseband LVDS Input Timing Specifications
The BB LVDS RX outputs have three different output timing modes, DDR0, DDR1 and DDR2. DDR1 and DDR2
modes output data, and the BBclk output is centered over the data. In DDR0 mode, the data and clock are
edge-aligned. Different BBOUT pins are used for clock, frame, and data pins depending on the byte, nibble, and
serial modes. The DDR1 and DDR2 modes are shown in Table 12 and Figure 16. The DDR0 mode is shown in
Table 13 and Figure 17. Table 12 and Figure 16. DDR1 mode is used upto a BBclk frequency of 310 MHz.
DDR2 mode is used upto a BBclk frequency of 155 MHz. When the data rate is higher than 500 MHz, BBclk
above 250 MHz, the operating mode is DDR0. In this mode, the clock is aligned with the output data transition. In
DDR0 mode, the customer must delay the clock to meet the tsu and thi target for the baseband input. The tskw
time is measured as the relative skew for the data and frame to the clock output. This is shown in Figure 13 and
Table 17.
In receive (uplink) mode, the GC5330 outputs data using the LVDS pins BBOUT. The BBOUT port may be
operated in three modes, DDR0, DDR1, and DDR2.
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The lowest-rate outputs use DDR2 mode, where the output clock changes on one rising edge of the internal
clock and the output data changes on the subsequent rising edge. In DDR2 mode, the output bit rate (per LVDS
pair) is half of the internal clock. Middle-rate outputs use DDR1 mode, where the output clock changes on the
falling edge of the internal clock and the output data changes on the rising edge of the internal clock, which
results in an output bit rate equal to the internal clock rate. Both DDR1 and DDR2 result in the output clock edge
occurring in the middle of output data-stable time. The DDR1 and DDR2 modes are shown in Table 12 and
Figure 16.
The highest-rate outputs use DDR0 mode, where both the output clock and output data change with both the
rising and falling edges of the internal clock. The DDR0 output bit rate is twice the internal clock rate. DDR0
results in the clock and data changing at the same time, and typically requires extra trace length on the PC board
for the clockout signal to provide the required setup time for the receiving chip. The DDR0 mode is shown in
Table 13 and Figure 17.
Table 12. General Switching Characteristics, RX BB LVDS Output – DDR1, DDR2
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
BASEBAND INTERFACE DDR LVDS
fCLK(BB-DDR2)
fCLK(BB-DDR1)
tskmin(BB)Serial0
Baseband output clock frequency
See (1). Applies to BBOUT byte,
nibble, or serial
BBOUT3 Clk, BBOUT1:0 Data, BBOUT2 Sync
See
(2) (3)
–20
ps
350
ps
155
310
MHz
tskmax (BB)Serial0
BBOUT3 Clk, BBOUT1:0 Data, BBOUT2 Sync
See
(2) (3)
tskmin(BB)Serial1
BBOUT7 Clk, BBOUT5:4 Data, BBOUT6 Sync
See
(2) (3)
15
ps
tskmax (BB)Serial1
BBOUT7 Clk, BBOUT5:4 Data, BBOUT6 Sync
See
(2) (3)
310
ps
tskmin(BB)Serial2
BBOUT11 Clk, BBOUT9:8 Data, BBOUT10 Sync
See
(2) (3)
60
ps
tskmin(BB)Serial2
BBOUT11 Clk, BBOUT9:8 Data, BBOUT10 Sync
See
(2) (3)
300
ps
tskmax(BB)Nibble0
BBOUT3 Clk, BBOUT5,4,1,0 Data, BBOUT2 Sync
See
(2) (3)
170
ps
tskmax(BB)Nibble0
BBOUT3 Clk, BBOUT5,4,1,0 Data, BBOUT2 Sync
See
(2) (3)
340
ps
tskmin(BB)Nibble1
BBOUT7 Clk, BBOUT11:8 Data, BBOUT6 Sync
See
(2) (3)
55
ps
tskmax(BB)Nibble1
BBOUT7 Clk, BBOUT11:8 Data, BBOUT6 Sync
See
(2) (3)
305
ps
tskmin(BB)Byte
BBOUT7 Clk, BBOUT11:8,5:4,2:0 Data, BBOUT6
Sync
See
(2) (3)
250
ps
tskmax(BB)Byte
BBOUT7 Clk, BBOUT11:8,5:4,2:0 Data, BBOUT6
Sync
See
(2) (3)
255
ps
(1)
(2)
(3)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Skew measured for RX BBOUT data and frame signals, relative to the BBclk signal at zero crossing. BBclk is measured at threshold
crossing. Lab measurement +signal → 50 Ω → Vcommon → 50 Ω → –signal. Vcommon has a 0.01-µF filter capacitor to GND.
Differential probe used for measurement.
tsu calculation: 1/4 BBclk period – tskmin; th calculation: 1/4 BBclk period – tskmax
BBOUT Clk
BBOUT Sync
BBOUT Data
tsu
th
T0508-01
Figure 16. RX Baseband LVDS DDR1, DDR2 Output Timing Specifications
32
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Table 13. General Switching Characteristics, RX BB LVDS Output – DDR0
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
BASEBAND INTERFACE DDR LVDS
fCLK(Byte)
Baseband output clock frequency
See (1)
384
MHz
fCLK(Nibble0)
384
MHz
fCLK(Nibble1)
500
MHz
fCLK(Serial)
384
MHz
(2) (3)
–60
ps
400
ps
–130
ps
See (2) (3) (4)
500
ps
BBOUT7 Clk, BBOUT5:4 Data, BBOUT6
Sync
See (5) (6)
–45
ps
tskmin(BB)Serial2
BBOUT7 Clk, BBOUT5:4 Data, BBOUT6
Sync
See (5) (6) (7)
425
ps
tskmax(BB)Nibble0
BBOUT3 Clk, BBOUT5,4,1,0 Data, BBOUT2
Sync
See (5) (6)
0
ps
tskmin(BB)Nibble0
BBOUT3 Clk, BBOUT5,4,1,0 Data, BBOUT2
Sync
See (5) (6) (7)
400
ps
tskmax(BB)Nibble1
BBOUT7 Clk, BBOUT11:8 Data, BBOUT6
Sync
See (5) (6)
10
ps
tskmin(BB)Nibble1
BBOUT7 Clk, BBOUT11:8 Data, BBOUT6
Sync
See (5) (6) (7)
460
ps
tskmax(BB)Byte
BBOUT7 Clk, BBOUT11:8,5:4,2:0 Data,
BBOUT6 Sync
See (5) (6)
0
ps
tskmin(BB)Byte
BBOUT7 Clk, BBOUT11:8,5:4,2:0 Data,
BBOUT6 Sync
See (5) (6) (7)
480
ps
tskmax(BB)Serial0
BBOUT3 Clk, BBOUT1:0 Data, BBOUT2
Sync
See
tskmin(BB)Serial0
BBOUT3 Clk, BBOUT1:0 Data, BBOUT2
Sync
See (2) (3) (4)
tskmax(BB)Serial1
BBOUT3 Ck, BBOUT1:0 Data, BBOUT2
Sync
See (2) (3)
tskmin(BB)Serial1
BBOUT3 Clk, BBOUT1:0 Data, BBOUT2
Sync
tskmax(BB)Serial2
(1)
(2)
(3)
(4)
(5)
(6)
(7)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Skew measured for RX BBOUT data and frame signals, relative to the BBclk signal at zero crossing. BBclk is measured at threshold
crossing. Lab measurement +signal → 50 Ω → Vcommon → 50 Ω → –signal. Vcommon has a 0.01-µF filter capacitor to GND.
Differential probe used for measurement.
The customer interface design modifies the trace lengths based on the desired receiver timing and clock delays.
tsu = –tskmax; thold = 1/4 BBclk period – tskmin.
Skew measured for RX BBOUT data and frame signals, relative to the BBclk signal at zero crossing. BBclk is measured at threshold
crossing. Lab measurement +signal → 50 Ω → Vcommon → 50 Ω → –signal. Vcommon has a 0.01-µF filter capacitor to GND.
Differential probe used for measurement.
The customer interface design modifies the trace lengths based on the desired receiver timing and clock delays.
tsu = –tskmax; thold = 1/4 BBclk period – tskmin.
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BBOUT Data, BBOUT Sync
BBOUT Clk
tskmax
tskmin
tskmin
tskmax
Ideal
Data
Placement
Ideal
Data
Placement
T0509-01
Figure 17. RX Baseband LVDS DDR0 Output Timing Specifications
The DAC TX interface has a 40-signal output bus. The DAC TX bus can provide 4-byte-wide or 2-word-wide
interfaces. Table 5 shows the different DAC devices that can be connected to the TX output ports. The DAC TX
interface has two styles of clock output, one where the DDR clock is centered over the output data-stable time,
and one where the clock transition is aligned with the data transition. If the output clock rate is greater than
500 MHz, the GC533x must be configured for clock transition aligned with the data transition. Depending on the
DAC type selected, the clock, frame, and data for the DAC may require a trace routing delay for proper
alignment. See Table 14, Table 15, and Table 16.
Table 14. TX DAC and Envelope Modulator Characteristics
DAC or Envelope Modulator
Type
Timing Model
DAC Data Rate
Table Number
Figure Number
DAC3282, 3283 byte-envelope
modulator
Clock centered over data
<1000 Mbyte/s
Table 15
Figure 18
DAC3282, 3283 byte-envelope
modulator
Clock aligned with data at GC533x, routing
provides timing skew for clock centered over data
≥1000 Mbyted/s
Table 16
Figure 19
DAC3484, 3482 word
Clock centered over data
<1000 Mword/s
Table 15
Figure 18
DAC3484, 3482 word
Clock aligned with data at GC533x, routing
provides timing skew for clock centered over data
≥1000 Mword/s
Table 16
Figure 19
DAC5682
Clock aligned with data at GC533x. PC board
routing may be required to provide some timing
skew for optimum performance.
All
Table 16
Figure 19
34
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Table 15. TX DAC Clock Centered Over Data Switching Characteristics (See Table 5 for Connections)
PARAMETER
TEST CONDITIONS
MIN
MAX
UNIT
620
MHz
MIN
SKEW
MAX
SKEW
UNIT
DDR LVDS
fCLK(DAC)
DAC output clock frequency
CLOCK
TXA4
See (1)
DATA
TXA9:5, 3:0
TEST CONDITIONS
See
(2) (3)
–190
139
ps
TXA14
TXA19:15, 13:10
See
(2) (3)
–241
205
ps
TXA9
TXA19:10, 8:0
See
(2) (3)
–200
155
ps
TXB4
TXB9:5, 3:0
See
(2) (3)
–169
238
ps
–198
146
ps
–145
235
ps
TXB14
TXB19:15, 13:10
See
(2) (3)
TXB9
TXB19:10, 8:0
See
(2) (3)
(1)
(2)
(3)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Skew measured from DAC DATA desired P/N crossing to DATA P/N crossing. A negative skew is when the data arrives prior to the
clock.
tsu = 1/4 DAC clock period – Max. Skew, th = 1/4 DAC clock period + Min. Skew
Table 16. TX DAC Clock Aligned With Data Switching Characteristics (See Table 5 for Connections)
PARAMETER
TEST CONDITIONS
MIN
MAX
UNIT
620
MHz
MIN
SKEW
MAX
SKEW
UNIT
DDR LVDS
fCLK(DAC)
DAC output clock frequency
CLOCK
See
(1)
DATA
TEST CONDITIONS
TXA4
TXA9:5, 3:0
See
(2)
–190
139
ps
TXA14
TXA19:15, 13:10
See
(2)
–241
205
ps
TXA9
TXA19:10, 8:0
See
(2)
–200
155
ps
TXB4
TXB9:5, 3:0
See
(2)
–169
238
ps
TXB14
TXB19:15, 13:10
See
(2)
–198
146
ps
TXB9
TXB19:10, 8:0
See
(2)
–145
235
ps
(1)
(2)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Skew measured from DAC DATA desired P/N crossing to DATA P/N crossing. A negative skew is when the data arrives prior to the
clock.
DAC Data, DAC Frame
DAC Data Clock
Min
Skew
Max
Skew
Max
Skew
Min
Skew
Ideal Data Placement
T0510-01
Figure 18. TX LVDS Timing Specifications (TXA and TXB) (DACCLK Centered Over Data)
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DAC Data, DAC Frame
DAC Data Clock
Min
Skew
Min
Skew
Max
Skew
Max
Skew
Ideal
Data
Placement
Ideal
Data
Placement
T0511-01
Figure 19. TX LVDS Timing Specifications (TXA and TXB) (DACCLK Aligned With Data)
The envelope modulator interface uses the same pins as the DAC interface. The ET connections are shown in
Table 5. The ET modulator timing is listed in Table 15.
Data is output most-significant byte (half-word) first with the rising edge of the clockout in the middle of
data-stable time, then least-significant byte (half-word) with the falling edge of the clockout in the middle of the
data-stable time.
The ADC output interface has two types of timing, based on the clock centered over the data, or clock
edge-aligned with the data. The GC533x only processes clock centered over the data. Each ADC type is
characterized by the data and clock alignment, in Table 17, from which the proper table and timing diagram can
be determined as follows: ADC W7 in Table 18 and Figure 20; ADC W14 in Table 19 and Figure 21; and ADC
B7 in Table 20 and Figure 20. Note: The general ADC routing is to align the clock and data traces with a
common routing delay. For the ADS5463 and ADS5474 the clock trace must be adjusted in length to meet the
system timing design.
Note: when RXA is used as a baseband interface, the specification is shown in table Table 17. The table shows
a sampling of ADCs released at publication time. If the clock is not centered, the pc board may require added
routing delay to the clock out to satisfy the setup time requirements. See (*) in Table 17.
W7 – word-wide ADC interface, clock on bit 7
W14 – word-wide ADC interface, clock on bit 14
B7 – byte-wide ADC interface, clock on bit 7
B14 – byte-wide ADC interface, clock on bit 14
36
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Table 17. General LVDS ADC Interface Table
ADC Type
Bits per Rail
Clock
Centered
ADC Format
ADC Input Timing Table
ADC Figure
ADS5400
1
Yes
W7
Table 18
Figure 20
ADS54RF63 (*)
1
No
W14
Table 19
Figure 20
ADS5463 (*)
1
No
W14
Table 19
Figure 20
ADS5474 (*)
1
No
W14
Table 19
Figure 20
RXA as baseband
TX input
2
Yes
Baseband format – W14
Table 21
Figure 20
ADS61xx, ADS41xx,
2
ADS62pxx
Yes
B7
Table 20
Figure 20
ADS55xx
2
Yes
B7, W7
Table 20Table 18
Figure 20
ADS58B18
2
Yes
B7, W7
Table 20Table 18
Figure 20
ADS58B28,
ADS62c1x
2
Yes
B7, W7
Table 20Table 18
Figure 20
ADS64xx
6 or 7
Yes
W7
Table 18
Figure 21
ADS52xx
12 or 14
Yes
W7
Table 18
Figure 21
Table 18. RX ADC-W7 Switching Characteristics
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
620
MHz
See
(1)
tsu(ADC,A)
Input data setup time on port A before ADCA7
Clk transition
See
(1) (2)
260
ps
th(ADC,A)
Input data hold time on port A after ADCA7 Clk
transition
See
(1) (2)
170
ps
tsu(ADC,B)
Input data setup time on port B before ADCB7
Clk transition
See
(1) (2)
260
ps
th(ADC,B)
Input data hold time on port B after ADCB7 Clk
transition
See
(1) (2)
140
ps
fCLK(ADC)
RX input clock frequency, ADCA7 Clk
(1)
(2)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Setup and hold times apply to data and appropriate ADC Clk, respectively. Timing is measured from ADC Clk threshold crossing.
ADC Clock
ADC Data
tsu
th
th
tsu
T0512-01
Figure 20. RX ADC LVDS Timing Specifications (RXA and RXB)
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Table 19. RX ADC-W14 Switching Characteristics
PARAMETER
TEST CONDITIONS
fCLK(ADC)
RX input clock frequency ADCA14 Clk,
ADCB14 Clk
tsu(ADC,A)
MIN
NOM
MAX
UNIT
620
MHz
See
(1)
Input data setup time on port A before
ADCA14 Clk transition
See
(1) (2)
160
ps
th(ADC,A)
Input data hold time on port A after
ADCA14 Clk transition
See
(1) (2)
200
ps
tsu(ADC,B)
Input data setup time on port B before
ADCB14 Clk transition
See
(1) (2)
180
ps
th(ADC,B)
Input data hold time on port B after
ADCB14 Clk transition
See
(1) (2)
220
ps
(1)
(2)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Setup and hold times apply to data and appropriate ADC Clk, respectively. Timing is measured from ADC Clk threshold crossing.
Table 20. RX ADC-B7, B14 Switching Characteristics
MAX
UNIT
fCLK(ADC-AB)
RX input clock frequency, ADCA7 Clk,
ADCB7 Clk
PARAMETER
See
(1)
620
MHz
fCLK(ADC-C)
RX input clock frequency, ADCC7 Clk
See
(1)
620
MHz
tsu(ADC,A)
Input data setup time on port A before
ADCA7 Clk transition
See
(1) (2)
260
ps
th(ADC,A)
Input data hold time on port A after
ADCA7 Clk transition
See
(1) (2)
160
ps
tsu(ADC,B)
Input data setup time on port B before
ADCB7 Clk transition
See
(1) (2)
170
ps
th(ADC,B)
Input data hold time on port B after
ADCB7 Clk transition
See
(1) (2)
140
ps
tsu(ADC,C)
Input data setup time on port C before
ADCC7 Clk transition
See
(1) (2)
290
ps
th(ADC,C)
Input data hold time on port C after
ADCC7 Clk transition
See
(1) (2)
150
ps
tsu(ADC,A)
Input data setup time on port A before
ADCA14 Clk transition
See
(1) (2)
130
ps
th(ADC,A)
Input data hold time on port A after
ADCA14 Clk transition
See
(1) (2)
200
ps
tsu(ADC,B)
Input data setup time on port B before
ADCB14 Clk transition
See
(1) (2)
170
ps
th(ADC,B)
Input data hold time on port B after
ADCB14 Clk transition
See
(1) (2)
240
ps
(1)
(2)
38
TEST CONDITIONS
MIN
NOM
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Setup and hold times apply to data and appropriate ADC Clk, respectively. Timing is measured from ADC Clk threshold crossing.
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ADC Clock
ADC Frame Clock
ADC Data
tsu
th
th
tsu
T0513-01
Figure 21. RX ADC LVDS Timing Specifications (RXA and RXB)
Table 21. RXA-BB Switching Characteristics
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
250
MHz
fCLK(BB-A)
RX input clock frequency
See
(1)
tsu(BB-A)
Input data setup time on port A before
ADCA Clk transition
See
(1) (2)
160
ps
th(BB-A)
Input data hold time on port A after
ADCA Clk transition
See
(1) (2)
200
ps
(1)
(2)
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Setup and hold times apply to data and appropriate ADC Clk, respectively. Timing is measured from ADC Clk threshold crossing.
Table 22. DPD Clock and Sync A,B Switching Characteristics (1)
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
MHz
fCLK(DPD)
DPD input clock frequency
See
(2)
310
{370}
fCLK(BB)
BB internal clock frequency
See
(1)
250
{290}
tDUTY-CYCLE
DPD input clock duty cycle
See
(3)
DPD clock input jitter
See
(3)
Input data setup time before fCLK↑
See
(2)
0.25
ns
fCLK
(JITTERRMS-DPD)
tsu(SYNCA)
40%
MHz
60%
2.5%
th(SYNCA)
Input data hold time after fCLK↑
See
(2)
0.1
ns
tsu(SYNCB)
Input data setup time before fCLK↑
See
(2)
0.35
ns
th(SYNCB)
Input data hold time after fCLK↑
See
(2)
0.05
ns
(1)
(2)
(3)
The PLL output ranges are 400–1000 MHz. These are configuration dependent but related to the DPDCLK frequency. The cmd5330
software automatically checks these limits when compiling a configuration.
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Specification is from the PLL specification and is not production tested.
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DPD Clock
SYNCA, SYNCB
tsu
th
T0514-01
4 cycles, min.
Figure 22. SYNCA, SYNCB Timing to DPD Clock
Table 23. DPD Clock and Sync Out Switching Characteristics
PARAMETER
TEST CONDITIONS
td(SYNCOut)
Data valid after DPD clock
See
(1)
tHO(SYNCOut)
Data held valid after next DPD clock
See
(1)
(1)
MIN
NOM
MAX
UNIT
0.95
ns
0.3
ns
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Sync Out
DPD Clock
td
tHO
T0515-01
Figure 23. Sync Out Timing to DPD Clock
The JTAG test connections are used with the CMOS signals for board interconnection tests. The TRSTB pin
must be toggled low, or low initially. If JTAG is not used, the TRSTB signal should be GROUNDed or tied to
GND through < 1 kΩ resistance. TRSTB should be 0 for normal operation.
Table 24. JTAG Switching Characteristics
PARAMETER
TEST CONDITIONS
MIN
MAX
UNIT
50
MHz
fTCK
JTAG clock frequency
tTCKL
JTAG clock low period
See
(1)
10
ns
tTCKH
JTAG clock high period
See
(1)
10
ns
tsu(TDI,TMS)
Input data setup time before fTCK↑
See
(1)
tH(TDI,TMS)
Input data hold time after fTCK↑
See
(1)
td
Output data delay from fTCK↓
See
tOHD(TDO)
Previous data valid from fTCK↓
See
(1)
40
7
ns
(1)
10
ns
(1)
2
ns
1.5
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
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t
TCK
TDI
tSU
tH
TDO
td
tOH
T0289-02
Figure 24. JTAG Timing Specifications
The SPI programming interface is active only when EMIFENA is 0. There are both three-wire and four-wire SPI
interfaces; the SPIDO(SPARE) is the fourth wire for SPI data output.
Table 25. SPI Switching Characteristics
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
tsu(DENB)
Enable setup time before SPI CLK↑
Valid for SPIDENB, see (1)
5
ns
tsu(DI)
Data setup time before SPI CLK↑
Valid for SPIDIO, see (1)
5
ns
(1)
0.6
th(DI)
Input data hold time after CLK↑
Valid for SPIDIO, see
td(DO)
Output data delay from fTCK↓
Valid for SPIDIO, see (2)
8
ns
td(DO1)
Output data delay from fTCK↓
Valid for SPIDO(SPARE), see (2)
8
ns
50
MHz
fclk SPI
(1)
(2)
SPI clock frequency
See
(1)
ns
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
The SPI data output in three-wire mode comes from SPIDIO; in four-wire mode the output is from SPIDO(SPARE).
SPI Clock
tsu(DENB)
th(DI)
SPIENB
tsu(DI)
SPIDIO-In
SPIDO(SPARE)
td(DO1)
th(DO)
T0516-01
Figure 25. SPI Timing Specifications
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Table 26. MPU Switching Characteristics (READ)
PARAMETER
TEST CONDITIONS
See (1)
CEB and ADDR setup time to ↓OEB
tsu(RD)
MIN MAX
1.5
(1)
tdly(RD)
Data valid time after ↓OEB
See
th(RD)
CEB and ADDR hold time to ↑OEB
See (1)
2.5
tHIGH(RD)
Time OEB must remain HIGH between READs
See (1)
6
tz(RD)
Data goes to high-impedance state after ↑OEB or ↑CEB
See (2)
tcycle(RD)
Time between READs
See
toh(RD)
Time after OEB↑ that data is valid
See
(1)
(2)
ns
15
ns
21
(2)
ns
ns
5
(1)
UNIT
ns
ns
TBD
ns
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
Bench tested for output start changing after releasing strobe with a 50-Ω load on the output
CEB
tsu(RD)
th(RD)
tsu(RD)
th(RD)
Addr
WEB
OEB
tdly(RD)
toh(RD)
tz(RD)
Data
T0517-01
Figure 26. MPU READ Timing Specifications
Table 27. MPU Switching Characteristics (WRITE)
PARAMETER
TEST CONDITIONS
CEB, DATA, and ADDR setup time to ↓WEB
tsu(WR)
MIN MAX
UNIT
See (1)
1.4
ns
(1)
th(WR)
CEB, DATA, and ADDR hold time after ↑WEB
See
3
ns
tlow(WR)
Time WEB and CEB must remain simultaneously LOW
See (1)
4
ns
thigh(WR)
Time CEB or WRB must remain HIGH between WRITEs
See (1)
7
ns
(1)
11
ns
tcycle(WR)
(1)
42
Time between WRITEs
See
Chip specifications are production tested at 90°C case temperature for the given specification. Early production lots are sample tested
at –40°C.
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CEB
tsu(WR)
th(WR)
tsu(WR)
th(WR)
Addr
OEB
tlow(WR)
thigh(WR)
WEB
th(WR)
tsu(WR)
Data
T0518-01
Figure 27. MPU WRITE Timing Specifications
Power Sequencing Guideline
TI ASIC I/O design allows either the core supply (VDD) or the I/O supply (VDDS) to be powered up (2) for an
indefinite period of time while the other power supply is not powered up, if all of these constraints are met:
• Chip is within all maximum ratings and recommended operating conditions.
• Have followed all warnings about exposure to maximum rated and recommended conditions, particularly
junction temperature. These apply to power transitions as well as normal operation.
• Bus contention while VDDS is powered up must be limited to 100 hours over the projected lifetime of the
device.
• Bus contention while VDDS is powered down may violate the absolute maximum ratings.
However, it is generally good practice to power up VDD, VDDSHV, and VDDS all within 1 second of each other.
Application Information
The GC533x reference design includes the following additional transmit/receive signal chain components:
• TMS320C6748 digital signal processor (DSP) and DPD adaptation software
• DAC3283 16-bit 800-MSPS, dac348X, or DAC5682 16-bit, 1-GSPS DAC (transmit path)
• CDCE72010 clock generator
• TRF3720 300-MHz to 4.8-GHz quadrature modulator with integrated wideband PLL/VCO
• TRF370317 0.4-GHz to 4-GHz quadrature modulator
• ADS41B49 14-bit, 250-MSPS ADC (and other options; feedback path)
• AMC7823 analog monitoring and control circuit with GPIO and SPI
• PGA870 wideband programmable gain amplifier
• ADS42b49 14-bit dual 250-MSPS receive or complex feedback ADC (and other options; RX path)
MPU Interface Guidelines
The following section describes the hardware interface between the recommended microprocessor and the
GC533x. The GC533x interface is an EMIF asynchronous interface.
(2)
A supply bus is powered up when the voltage is within the recommended operating range. It is powered down when it is below that
range, either stable or in transition.
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The TMS320C674x/OMAP-L1x Processor Peripherals Overview referencde guide (SPRUFK9) illustrates the
connections to the TMS320C6748 peripherals. The TMS320C674x/OMAP-L1x Processor External Memory
Interface A (EMIFA) user's guide (SPRUFL6) illustrates the connections to the EMIF A interface, and DSP timing.
It is recommended that if more than one EMIF-A load is connected to the DSP, buffering is used for the control
bus WE, RD, address bus, and data bus.
Related Material and Documents
The following documents are available through your TI Field Application Engineer FAE:
• GC5330 EVM schematic diagram
• GC5330 EVM layout diagram
• GC533x Baseband Application Note
• GC533x Baseband beAGC Application Note
• GC533x DDUC Application Note
• GC533x CFR Application Note
• GC533x DPD Application Note
• GC533x TX (BUC, DAC Interface) Application Note
• GC533x RX Application Note
• GC533x feAGC Application Note
• GC533x Sync, MPU Application Note
• GC533x Software Application Guide
44
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APPENDIX
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
BBclk
Clock-to-baseband section of GC533x
BW
Bandwidth
CCDF
Complementary cumulative distribution function
CDMA
Code division multiple access (spread spectrum)
CEVM
Composite error vector magnitude
CFR
Crest factor reduction
DPD_CLK
Clock-to-DPD section of GC533x
CIC
Cascaded integrator comb (type of digital filter)
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)
DPD
Digital pre-distortion
DSP
Digital signal processing or digital signal processor
DUC
Digital upconverter (usually provides the GC533x input)
EVM
Error vector magnitude
FIR
Finite impulse response (type of digital filter)
HP-DPD
High-performance DPD mode of the GC533x
HS-DPD
High-speed DPD mode of the GC533x
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
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)
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WiBro
Wireless Broadband (Korean initiative IEEE 802.16e)
WiMAX
Worldwide Interoperability of Microwave Access (IEEE 802.16e)
AA
AA
AA
REVISION HISTORY
Changes from Revision A (December 2010) to Revision B
Page
•
Revised GC533x block diagram ........................................................................................................................................... 7
•
Added text in next-to-last paragraph of Input and Output Syncs section ........................................................................... 28
•
Combined GC5330 and {GC5337} values into a single row in Table 22 ........................................................................... 39
•
Revised Figure 22 ............................................................................................................................................................... 40
•
Revised Figure 25 ............................................................................................................................................................... 41
46
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PACKAGE OPTION ADDENDUM
www.ti.com
9-Jul-2012
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package
Drawing
Pins
Package Qty
Eco Plan
(2)
Lead/
Ball Finish
MSL Peak Temp
(3)
Samples
(Requires Login)
GC5330IZEV
ACTIVE
BGA
ZEV
484
60
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
GC5337IZEV
ACTIVE
BGA
ZEV
484
60
Green (RoHS
& no Sb/Br)
SNAGCU
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.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
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