Definition The
link spectral efficiency of a digital communication system is measured in
bit/s/Hz, or, less frequently but unambiguously, in
(bit/s)/Hz. It is the
net bit rate (useful information rate excluding
error-correcting codes) or
maximum throughput divided by the
bandwidth in hertz of a
communication channel or a
data link. Alternatively and less commonly, spectral efficiency may be measured in
bit/symbol, which is equivalent to
bits per channel use (
bpcu). This can be calculated by dividing the net bit rate by the
symbol rate (modulation rate). Link spectral efficiency is typically used to analyze the efficiency of a
digital modulation method or
line code. Spectral efficiency calculations may or may not count bits used for
forward error correction (FEC) code and other physical layer overhead. If FEC overhead is excluded, a "bit" refers to a user data bit only. The
modulation efficiency in bit/s is the
gross bit rate, which includes any bits used for FEC, divided by the bandwidth. :
Example 1: A transmission technique using one
kilohertz of bandwidth to transmit 1,000 bits per second has a modulation efficiency of 1 (bit/s)/Hz. :
Example 2: A
V.92 modem for the telephone network can transfer 56,000 bit/s downstream and 48,000 bit/s upstream over an analog telephone network. Due to filtering in the telephone exchange, the frequency range is limited to between 300 hertz and 3,400 hertz, corresponding to a bandwidth of 3,400 − 300 = 3,100 hertz. The spectral efficiency or modulation efficiency is 56,000/3,100 = 18.1 (bit/s)/Hz downstream, and 48,000/3,100 = 15.5 (bit/s)/Hz upstream.
Upper Bound An upper bound for the attainable modulation efficiency is given by the
Nyquist rate or
Hartley's law as follows: For a signaling alphabet with
M alternative symbols, each symbol represents
N = log2
M bits.
N is the modulation efficiency measured in
bit/symbol or
bpcu. In the case of
baseband transmission (
line coding or
pulse-amplitude modulation) with a baseband bandwidth (or upper cut-off frequency)
B, the
symbol rate can not exceed 2
B symbols/s in view to avoid
intersymbol interference. Thus, the spectral efficiency can not exceed 2
N (bit/s)/Hz in the baseband transmission case. In the
passband transmission case, a signal with passband bandwidth
W can be converted to an equivalent baseband signal (using
undersampling or a
superheterodyne receiver), with upper cut-off frequency
W/2. If double-sideband modulation schemes such as
QAM,
ASK,
PSK or
OFDM are used, this results in a maximum symbol rate of
W symbols/s, and in that the modulation efficiency can not exceed
N (bit/s)/Hz. If digital
single-sideband modulation is used, the passband signal with bandwidth
W corresponds to a baseband message signal with baseband bandwidth
W, resulting in a maximum symbol rate of 2
W and an attainable modulation efficiency of 2
N (bit/s)/Hz. :
Example 3: A 16QAM modem has an alphabet size of
M = 16 alternative symbols, with
N = 4 bit/symbol or bpcu. Since QAM is a form of double sideband passband transmission, the spectral efficiency cannot exceed
N = 4 (bit/s)/Hz. :
Example 4: The
8VSB (8-level vestigial sideband) modulation scheme used in the
ATSC digital television standard gives
N=3 bit/symbol or bpcu. Since it can be described as nearly single-side band, the modulation efficiency is close to 2
N = 6 (bit/s)/Hz. In practice, ATSC transfers a gross bit rate of 32 Mbit/s over a 6 MHz wide channel, resulting in a modulation efficiency of 32/6 = 5.3 (bit/s)/Hz. :
Example 5: The downlink of a V.92 modem uses a pulse-amplitude modulation with 128 signal levels, resulting in
N = 7 bit/symbol. Since the transmitted signal before passband filtering can be considered as baseband transmission, the spectral efficiency cannot exceed 2
N = 14 (bit/s)/Hz over the full baseband channel (0 to 4 kHz). As seen above, a higher spectral efficiency is achieved if we consider the smaller passband bandwidth.
With Forward Error Correction If a
forward error correction code is used, the spectral efficiency is reduced from the uncoded modulation efficiency figure. :
Example 6: If a forward error correction (FEC) code with
code rate 1/2 is added, meaning that the encoder input bit rate is one half the encoder output rate, the spectral efficiency is 50% of the modulation efficiency. In exchange for this reduction in spectral efficiency, FEC usually reduces the
bit-error rate, and typically enables operation at a lower
signal-to-noise ratio (SNR). An upper bound for the spectral efficiency possible without
bit errors in a channel with a certain SNR, if ideal error coding and modulation is assumed, is given by the
Shannon–Hartley theorem. :
Example 7: If the SNR is 1, corresponding to 0
decibel, the link spectral efficiency can not exceed 1 (bit/s)/Hz for error-free detection (assuming an ideal error-correcting code) according to Shannon–Hartley regardless of the modulation and coding.
Discussion Note that the
goodput (the amount of application layer useful information) is normally lower than the
maximum throughput used in the above calculations, because of packet retransmissions, higher protocol layer overhead, flow control, congestion avoidance, etc. On the other hand, a data compression scheme, such as the
V.44 or
V.42bis compression used in telephone modems, may however give higher goodput if the transferred data is not already efficiently compressed. The link spectral efficiency of a wireless telephony link may also be expressed as the maximum number of simultaneous calls over 1 MHz frequency spectrum in erlangs per megahertz, or
E/MHz. This measure is also affected by the source coding (data compression) scheme. It may be applied to analog as well as digital transmission. In wireless networks, the
link spectral efficiency can be somewhat misleading, as larger values are not necessarily more efficient in their overall use of radio spectrum. In a wireless network, high link spectral efficiency may result in high sensitivity to co-channel interference (crosstalk), which affects the capacity. For example, in a
cellular telephone network with frequency reuse,
spectrum spreading and
forward error correction reduce the spectral efficiency in (bit/s)/Hz but substantially lower the required signal-to-noise ratio in comparison to non-spread spectrum techniques. This can allow for much denser geographical frequency reuse that compensates for the lower link spectral efficiency, resulting in approximately the same capacity (the same number of simultaneous phone calls) over the same bandwidth, using the same number of base station transmitters. As discussed below, a more relevant measure for wireless networks would be
system spectral efficiency in bit/s/Hz per unit area. However, in closed communication links such as telephone lines and cable TV networks, and in noise-limited wireless communication system where co-channel interference is not a factor, the largest link spectral efficiency that can be supported by the available SNR is generally used. == System spectral efficiency or area spectral efficiency ==