802.11a Physical Layer Revealed

By Jim Geier

March 14, 2003

802.11a is becoming more popular as companies find advantages of implementing 5GHz wireless LANs. Learn how the 802.11a Physical Layer works and what you should consider when installing 802.11a networks.

In a previous tutorial, we discussed the inner workings of the 802.11b Physical (PHY) Layer. Similar to 802.11b, the 802.11a PHY Layer specifies the transmission and reception of 802.11 frames. Now we'll take a look inside the 802.11a PHY Layer, which uses orthogonal frequency division multiplexing (OFDM) technology to support operation of up to 54Mbps data rates in the 5GHz band.

802.11a PLCP Frame Fields

The 802.11a PHY Layer Convergence Procedure (PLCP) transforms each 802.11 frame that a station wishes to send into a PLCP protocol data unit (PPDU). The PPDU includes the following fields in addition to the frame fields imposed by the Medium Access Control (MAC) Layer:

  • PLCP Preamble. This field consists of 12 symbols and enables the receiver to acquire an incoming OFDM signal.
  • Rate. This field identifies the data rate of the 802.11 frame. As with 802.11b, the 802.11a PLCP fields, however, are always sent at the lowest rate, which is 6Mbps. The following represents the data rates represented by specific field values:

Field Value

Data Rate

1101

6Mbps

1111

9Mbps

0101

12Mbps

0111

18Mbps

1001

24Mbps

1011

36Mbps

0001

48Mbps

0011

54Mbps

  • Reserved. This field is set to a logic zero.
  • ength. This field represents the number of octets contained with the frame.
  • Parity. Based on values of the Rate, Reserved, and Length fields, this field contains a single-bit value that provides positive (even) parity.
  • Tail. This field is always set to logic zeros.
  • Service. This field consists of seven bits as logic zeros to synchronize the descrambler in the receiver and another nine bits (currently all logic zeros) reserved for future use.
  • PSDU. The PSDU, which stands for Physical Layer Service Data Unit, represents the contents of the PPDU (i.e., the actual 802.11 frame being sent).
  • Tail. This field consists of six bits (all zeros) for receiver processing functions.
  • Pad Bits. This field contains a number of bits in order to modify the frame size to equal a specific multiple of bits coded in an OFDM symbol.

As with 802.11b, 802.11 analyzers don't display the 802.11a PHY Layer fields. The 802.11 radio card removes the fields before processing occurs by the MAC Layer.

OFDM in Operation

OFDM is not a form of spread spectrum. Instead, OFDM divides a data signal across 48 separate sub-carriers within a 20MHz channel to provide transmissions of 6, 9, 12, 18, 24, 36, 48, or 54Mbps. Data rates of 6Mbps, 12Mbps, and 24Mbps are mandatory for all 802.11-compliant products. OFDM is extremely efficient, which enables it to provide the higher data rates and minimize multi-path propagation problems.

An 802.11a modulator converts the binary signal into an analog waveform through the use of different modulation types, depending on which data rate is chosen. For example with 6Mbps operation, the PMD uses binary phase shift keying (BPSK), which shifts the phase of the transmit center frequency to represent different data bit patterns. The higher data rates, such as 54Mbps, employ quadrature amplitude modulation (QAM) to represent data bits by varying the transmit center frequency with different amplitude levels in addition to phase shifts.

Transmit Frequencies

The 802.11a PMD translates the signal into an analog form with a transmit center frequency corresponding to the radio channel chosen by the user. The corresponding operating frequencies in the U.S. fall into the national information structure (U-NII) bands: 5.15-5.25GHz, 5.25-5.35GHz, and 5.725-5.825GHz. Within this spectrum, there are twelve, 20MHz channels, and each band has different output power limits.

The following identifies the center frequency and maximum output power of each of the U-NII bands:

Frequency

Channel Number

Transmit Frequency

Maximum Transmit Power

U-NII lower band

40

5.200 GHz

40mW

36

5.180 GHz

44

5.220 GHz

48

5.240 GHz

U-NII middle band

52

5.260 GHz

200mW

56

5.280 GHz

60

5.300 GHz

64

5.320 GHz

U-NII upper band

149

5.745 GHz

800mW

153

5.765 GHz

157

5.785 GHz

161

5.805 GHz

OFDM is becoming very popular for high-speed transmission. In addition to being selected for use within the 802.11g PHY Layer, OFDM is the basis for the European-based HiperLAN/2 wireless LAN standards. In fact the 802.11a PHY Layer is very similar to the HiperLAN/2 PHY. In addition, OFDM has also been around for a while supporting the global standard for asymmetric digital subscriber line (ADSL).

Stay tuned: In future tutorials, we'll take a closer look at the 802.11 infrared and 802.11g physical layers as well.

Jim Geier provides independent consulting services to companies developing and deploying wireless network solutions. He is the author of the book, Wireless LANs and offers workshops on deploying wireless LANs.

Join Jim for discussions as he answers questions in the 802.11 Planet Forums.



Comment and Contribute
(Maximum characters: 1200). You have
characters left.