design and implementation of a wcdma uplink baseband...

Design and Implementation of a Design and Implementation of a WCDMA Uplink WCDMA Uplink BasebandBaseband Receiver ICReceiver IC

Hsi-Pin Ma (馬席彬)

Assistant ProfessorDepartment of Electrical Engineering

National Tsing Hua UniversityFeb. 12, 2004

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OutlineOutline

• Design Flow• Architecture Design• Simulation Channel Model• Functional Simulation Results• Circuit Design• Implementation and Measurements• Conclusions

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Design FlowDesign Flow

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Architecture DesignArchitecture Design

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Common Frame Structure in Uplink Common Frame Structure in Uplink Physical ChannelsPhysical Channels

[2]

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Transmitter Architecture and Transmitter Architecture and ConfigurationConfiguration

General Tx Architecture PRACH Transmission

PCPCH Transmission DPDCH & DPCCH Transmission

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Proposed Receiver ArchitectureProposed Receiver Architecture

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Receiver ConfigurationsReceiver Configurations

• (a) Preamble • (b) Message Part

& DPCH• (c) Disable

beamforming

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Criteria for Choosing Major System Criteria for Choosing Major System ParametersParameters

• Beamforming algorithm– Feasibility for IC implementation

• Matched filter– Fast acquisition for channel delay profile– Hardware efficiency– Area and power consumption

• Carrier Synchronization– Fast acquisition for frequency offset– Speed of convergence

• Timing Synchronization– Performance and Area

• RAKE combining algorithm– Performance

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Channel EstimatorChannel Estimator

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Carrier Synchronization Carrier Synchronization (1/2)(1/2)

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Carrier Synchronization Carrier Synchronization (2/2)(2/2)

• (a) Acquisition,• (b) Initial frequency

offset and phase shift calculation,

• (c) Tracking.

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RAKE CombiningRAKE Combining

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RAKE Combining ConceptRAKE Combining Concept

Finger 1Finger 2

Finger 3

Finger 4I

Q

Combined Signal

Q

I

Combining

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Phased Array AntennasPhased Array Antennas

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BasebandBaseband Complex Model for a Linear Complex Model for a Linear Equally Spaced ArrayEqually Spaced Array

DOA (θ,φ)

[14]

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BeamformingBeamforming ConceptConcept

CombiningAntenna 2

Antenna 3

Antenna 1

Antenna 4

I

Q

Combined Signal

Q

I

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BeamformerBeamformer/Beam Searcher/Beam Searcher

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Functional SimulationFunctional Simulation

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Simulation Channel ModelSimulation Channel Model

Scalar Channel Model

Vector Channel Model

Power Delay Profile

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Carrier Synchronization Carrier Synchronization (1/2)(1/2)

Preamble Symbols Phasor Difference

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Margin

Carrier Synchronization Carrier Synchronization (2/2)(2/2)

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RAKE CombinerRAKE Combiner

1st Path 2nd Path

Combined

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BeamformerBeamformer/Beam Searcher /Beam Searcher (1/3)(1/3)

2 users

11 users

Simulated Beam Pattern

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BeamformerBeamformer/Beam Searcher /Beam Searcher (2/3)(2/3)

w/o Beamformer w/ Beamformer

2 users

11 users

Matched Filter Output Under Beamformer Test

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BeamformerBeamformer/Beam Searcher /Beam Searcher (3/3)(3/3)

RAKE Combining Output

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Word Length DeterminationWord Length Determination

Input of matched filter

2

2

10log10σµ=SNR

∑=

=n

kkpI

n 1,0

1µ

∑=

−−

=n

kkpI

n 1

22,0

2

11 )( µσ

where

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System PerformanceSystem Performance

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Circuit DesignCircuit Design

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Channel EstimatorChannel Estimator

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Latch File StructureLatch File Structure

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Area ConsiderationArea Consideration

6T

22T

Latch

D-type flip flop

Synthesized Synthesized

CustomLayoutCustom

Layout

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Power Consumption ConsiderationPower Consumption Consideration

Conventional Correlation Method

Proposed Correlation Method

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Low Voltage Operation Consideration Low Voltage Operation Consideration (1/3)(1/3)

• Modified TSPC Ring Decoders– Lower power consumption– Fast response– Operate at low voltage

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Low Voltage Operation Consideration Low Voltage Operation Consideration (2/3)(2/3)

Faster response

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Low Voltage Operation Consideration Low Voltage Operation Consideration (3/3)(3/3)

Original TSPC split-output circuit Modified TSPC split-output circuit

Low Voltage Operation

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Carrier SynchronizationCarrier Synchronization

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RAKE CombinerRAKE Combiner

RAKE Combiner

Correlator

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Beam SearcherBeam Searcher

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BeamformerBeamformer & Phase De& Phase De--rotatorrotator

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Implementation and MeasurementImplementation and Measurement

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FloorplanFloorplan for the Receiverfor the Receiver

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Ratio of Each Building BlockRatio of Each Building BlockTransistor Count

Area

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Die PhotoDie Photo

Custom Layout

Synthesized (ROM)

Other : Automatic Placement & Routing

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Chip FeaturesChip Features

• Baseband processor for uplink W-CDMA receiving operating at 3.84 Mchip/s.

• Operation at 15.36 MHz sampling rate (four samples per chip) at a supply voltage of 2.15 V.

• Provision for both spatial diversity (beamforming) and path diversity (RAKE combiner).

• Low-power latch-file structure for the digital matched filter in the channel estimator.

• Low-complexity correlator-based beam searcher that supports real-time adaptive beamforming based on four-element antenna array.

• Special phase/frequency estimation hardware for fast carrier synchronization.

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Measurement EnvironmentMeasurement Environment

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Communication PerformanceCommunication Performance

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Power DissipationPower Dissipation

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ConclusionsConclusions

• Investigate major specifications for IMT-2000. • Design and implement a baseband receiver IC

conforming to 3GPP W-CDMA uplink transmission.• Improve the receiver performance with advanced

receiving technologies using low-complexity hardware.– RAKE combining– Beamformer

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Related PublicationsRelated Publications• Journal papers

– Hsi-Pin Ma, Ming-Luen Liou, and Tzi-Dar Chiueh, “A 123-mW Digital Beamforming Receiver for Third-Generation W-CDMA Uplink Communications,” accepted by IEEE Journal of Solid-State Circuits for publication.

– Yuan-Hao Huang, Hsi-Pin Ma, Ming-Luen Liou, and Tzi-Dar Chiueh, “An 1.1G MAC/s Sub-Word-Parallel Digital Signal Processor for Wireless Communication Applications,” accepted by IEEEJournal of Solid-State Circuits for publication.

– Hsi-Pin Ma, Steve Heng-Chen Hsu, and Tzi-Dar Chiueh, “Design and Implementation of an Uplink Baseband Receiver for Wideband CDMA Communications,” IEICE Trans. on Fundamentals of Electronics, Communications and Computer Sciences, vol. E85-A, No. 12, pp. 2813-2821, December 2002.

• Conference papers– Hsi-Pin Ma, and Tzi-Dar Chiueh, “Design and Implementation of an Uplink Baseband Receiver

IC for Wideband CDMA Communication Systems with Beamforming Capability,” 2002 VLSI Design/CAD Symposium, Taitung, August 12-15, 2002.

– Hsi-Pin Ma, Steve Hengchen Hsu, Tzi-Dar Chiueh, “Real-Time Baseband Signal Processing Module for Wideband CDMA Transceiver,” National Symposium on Telecommunications, December 2000.

– Hsi-Pin Ma, Steve Hengchen Hsu, and Tzi-Dar Chiueh, “An Uplink Baseband Receiver architecture and FPGA Implementation for W-CDMA Systems,” in the IEEE Proc. of the 6th Asia-Pacific Conference on Communications, Seoul, Korea, November 2000, pp. 774-778.

– T. D. Chiueh, H. P. Ma, and H. C. Hsu, “An Uplink Transceiver Architecture for Wideband CDMA Systems,” in Proc. 1999 IEEE International Symposium on Intelligent Signal Processing and Communication Systems (ISPACS’99), Phuket, Thailand, December 1999, pp. 577-580.

– 經濟部第三代通訊系統核心技術與WB-WCDMA/WLL系統發展研討會,民國八十八年四月