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RF Transmitters

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Title: RF Transmitters


1
RF Transmitters
  • Architectures for Integration and
  • Multi-Standard Operation

Terry Yao ECE 1352
2
Outline
  • Motivation
  • Transmitter Architectures
  • Current Trends in Integration
  • State-of-the-Art Examples (3)
  • Direct Conversion
  • 2-Stage
  • Future Challenges
  • References

3
Motivation
  • Increase in demand for low-cost,
    small-form-factor, low-power transceivers
  • Proliferation of various wireless standards
    pushes for multi-standard operation
  • CMOS is well suited for high levels of mixed
    signal radio integration 2
  • End goal a low cost single chip radio
    transceiver covering multiple RF standards

4
RF Transmitters
Performance Specification
Accuracy
Spectral Emission
Output Power Level
5
Transmitter Architectures
  • Mixer-Based
  • Direct Conversion (Homodyne)
  • 2-Stage Conversion (Heterodyne)
  • Both architectures can operate with constant and
    non-constant envelope modulation
  • Well-suited for multi-standard operation
  • PLL-Based
  • Show promise with respect to elimination of
    discrete components
  • Fundamentally limited to constant-envelope
    modulation schemes ? not suitable for
    multi-standard operation

6
Transmitter Architectures
  • Direct Conversion
  • Attractive due to simplicity of the signal path ?
    suitable for high levels of integration
  • Output carrier frequency local oscillator (LO)
    frequency
  • Important drawback LO disturbance by PA output

7
Transmitter Architectures
  • Direct Conversion LO Pulling
  • Noisy output of PA corrupts VCO spectrum
    -injection pulling or injection locking
  • VCO frequency shifts toward frequency of external
    stimulus
  • If injected noise frequency close to oscillator
    natural frequency, then LO output eventually
    locks onto noise frequency as noise level
    increases

8
Transmitter Architectures
  • Direct Conversion LO Frequency Offset Technique
  • LO pulling can be alleviated by moving the PA
    output spectrum sufficiently far from the LO
    frequency
  • LO offset can be achieved by mixing 2 VCO outputs
    ?1 and ?2 and filtering the result leading to a
    carrier frequency of ?1 ?2, far from either ?1
    or ?2
  • BPF1 must have high selectivity to suppress spurs
    of the form m?1m?2 to avoid degradation in
    quadrature generation and spurs in the
    up-converted signal

9
Transmitter Architectures
  • 2-Stage Up-Conversion
  • Another approach to solving the LO pulling
    problem
  • Up-convert in 2 stages so PA output spectrum is
    far from VCO frequency
  • Quadrature modulation at IF (?1), up-convert to
    ?1 ?2 by mixing and filtering
  • BPF1 suppresses the IF harmonics, while BPF2
    removes the unwanted sideband ?1- ?2
  • Advantages no LO pulling better I/Q matching
    (less crosstalk between the 2 bit streams)

10
Current Trends in Integrated Transceivers
  • Both direct and 2-stage architectures are used
    (with modifications for better integration and
    multi-standard operation)
  • Direct architecture ? achieves a low-cost
    solution with a high level of integration
    3,4,6,8
  • 2-stage ? results in better performance (ie.
    reduced LO pulling) at the expense of increased
    complexity and hence higher cost of
    implementation 5,7,9,10,11
  • Transmitter and receiver designed concurrently to
    enable hardware and possibly power sharing

11
Direct Conversion Example
  • A 5-GHz CMOS transceiver frontend chipset 6
  • Homodyne architecture for better integration,
    lower cost and lower power consumption
  • Uses on-chip quadrature VCO and buffers to
    improve frequency purity
  • On-chip VCO minimizes radiation leakage from
    strong PA output back to core oscillator
  • Buffers isolate sensitive VCO circuit from
    high-power, large voltage or current swing
    circuit blocks

12
2-Stage Conversion Example
  • A Dual Band (GSM 900-MHz/DCS1800 1.8-GHz) CMOS
    Transmitter 7
  • Exploits similarities of GSM and DCS1800
    standards (modulation, channel spacing, antenna
    duplexing) to reduce hardware
  • 2 quadrature upconverters driven by 450MHz LO to
    generate quadrature phases of IF signal
  • IF signal routed to single-sideband mixers driven
    by a 1350MHz LO, producing either 900MHz or
    1800MHz signal

13
2-Stage Conversion Example (2)
  • 1.75GHz Integrated Narrow-Band CMOS Transmitter
    with Harmonic-Rejection Mixers 5
  • Harmonic rejection mixer for IF up-conversion
    relaxes on-chip filtering requirements and even
    eliminates discrete IF filter ? better
    integration!
  • HRM not only does frequency translation, but also
    attenuates the 3rd and 5th IF harmonics by
    multiplying the baseband signal by a 3-bit,
    amplitude-quantized sinusoid

14
Future Challenges
  • Implementation of highly integrated radio
    transceivers will remain as one of the greatest
    challenges in IC technology
  • New architectures and circuit techniques should
    be investigated for higher flexibility in CMOS
    transmitters
  • Further improvement needed in the design of
    on-chip inductors, filters and oscillators in a
    standard CMOS process
  • Continued improvement in high frequency CMOS
    device modeling and simulation

15
References
  • 1. B. Razavi, RF Transmitter Architectures
    and Circuits, IEEE CICC, pp. 197-204, 1999.
  • 2. A. Abidi, et. al., The Future of CMOS
    Wireless Transceivers, ISSCC, pp. 118-119, Feb.
    1997.
  • 3. J. Rudell, et. al., Recent Developments in
    High Integration Multi-Standard CMOS Transceivers
    for Personal Communication Systems, IEEE 1998.
  • 4. S. Kim, et. al., A Single-Chip 2.4GHz
    Low-Power CMOS Receiver and Transmitter for WPAN
    Applications, IEEE 2003.
  • 5. J. Weldon, et. al., A 1.75-GHz Highly
    Integrated Narrow-Band CMOS Transmitter With
    Harmonic-Rejection Mixers, IEEE Journal of
    Solid-State Circuits, Vol. 36, No. 12, Dec. 2001.
  • 6. T. Liu, et. al., 5-GHz CMOS Radio
    Transceiver Front-End Chipset, IEEE Journal of
    Solid-State Circuits, Vol. 35, No. 12, Dec. 2000.
  • 7. B. Razavi, A 900-MHz/1.8-GHz CMOS
    Transmitter for Dual-Band Applications, IEEE
    Journal of Solid-State Circuits, Vol. 34, No. 5,
    May 1999.
  • 8. R. Point, et. al., An RF CMOS Transmitter
    Integrating a Power Amplifier and a
    Transmit/Receive Switch for 802.11b Wireless
    Local Area Network Applications, IEEE RF IC
    Symposium, pp 431-434, 2003.
  • 9. S. Aggarwal, et. al., A Highly Integrated
    Dual-Band Triple-Mode Transmit IC for CDMA2000
    Applications, IEEE BCTM 3.1, pp 57-60, 2002.
  • 10. X. Li, et. al., A CMOS 802.11b Wireless
    LAN Transceiver, IEEE RF IC Symposium, pp.
    41-44, 2003.
  • 11. S. Mehta, et. al., A CMOS Dual-Band
    Tri-Mode Chipset for IEEE 802.11a/b/g Wireless
    LAN, IEEE RF IC Symposium, pp 427-430, 2003.
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