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GC5316 SLWS154A ? JANUARY

2004 ? REVISED MARCH

2004 HIGH?DENSITY DIGITAL DOWNCONVERTER AND UPCONVERTER FEATURES D Optimized for CDMA2000?1X and UMTS D Up to

12 UMTS or

24 CDMA2000 Downconverter and Upconverter Channels D Mixed CDMA2000?1X and UMTS Operation D DDC Input and DUC Output Rates to

125 MSPS D Any DDC Can Connect to Any of Four Input Ports D Any DUC Can Sum into Any of Four Output Ports D Real/Complex DDC Inputs and DUC Outputs D Programmable AGC on DDC Outputs D Rx Filtering:

6 Stage CIC,

48 Tap CFIR,

64 Tap PFIR D Tx Filtering:

6 Stage CIC,

47 Tap CFIR,

63 Tap PFIR D 115-dB SFDR D 16-Bit DDC Inputs, 18-Bit DUC Outputs D 1.

5-V Core, 3.3-V I/O

1 Description The GC5316 is a high-density multi-channel communications signal processor integrated circuit that provides both digital downconversion and digital upconversion optimized for cellular base transceiver systems. The device supports both UMTS and CDMA2000 (CDMA) air interface cellular standards. The chip provides up to

24 CDMA digital downconverter (DDC) and digital upconverter (DUC) channels or

12 UMTS DDC and DUC channels. The GC5316 can also support a combination of CDMA and UMTS channels. The DDC and DUC channels are independent and operate simultaneously. The chip is ideal for cellular base transceiver systems where a large number of digital radio channels are required. Each of the

24 CDMA (or

12 UMTS) channels can operate independently. On the DDC side there are four

16 bit input ports that can accept real or complex input data. The input ports are driven with parallel data, typically from an analog-to-digital converter. Each downconverter channel can be programmed to accept data from any one of the four input ports. On the DUC side, there are four 18-bit output ports. Each output port can sum any of the DUC channels in a daisy-chain fashion. This permits creating a stack of CDMA or UMTS signals. These ports can output either real or complex data. Real output data would generally drive one or more D/A converters and output the stack of signals at an intermediate frequency (IF). Complex data (at baseband or an IF) is used when a quadrature modulator upconversion scheme is employed. Complex output data can also be used when the output stack is further processed using crest factor reduction or power amplifier predistortion techniques. Table of Contents

1 Description

1

2 GC5316 Receive

3

3 GC5316 Transmit

25

4 GC5316 General Control

45

5 GC5316 Programming

48

6 GC5316 Pin Description

62

7 Specification

70 PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. 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. www.ti.com Copyright ? 2004, Texas Instruments Incorporated GC5316 SLWS154A ? JANUARY

2004 ? REVISED MARCH

2004 www.ti.com

2 1.1 Functional Block Diagram

2 1

16 6 Control &

Sync

4 4 JTAG

16 16

16 16

2 1 Serial Baseband Receive Channel Outputs Serial Baseband Transmit Channel Inputs Receive Input Data Interface Receive Input Data (from A/Ds) tx_Iflag tx_clk_out txout_a txout_b txout_c txout_d rxin_a rxin_b rxin_c rxin_d adcclk d0?d15 a0?a5 rd_n wr_n ce_n rxclk txclk rx_sync a?d tx_sync a?d reset_n sync control sync control rx_sync_out tx_sync_out interrupt sync sync DDCs 2?9 DUCs 2?9 sync sync I&