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Spectral efficiency

January 01, 1970

Spectral efficiency, spectrum efficiency or bandwidth efficiency refers to the information rate that can be transmitted over a given bandwidth in a specific communication system. It is a measure of how efficiently a limited frequency spectrum is utilized by the physical layer protocol, and sometimes by the medium access control (the channel access protocol).[1]

Link spectral efficiency edit

The link spectral efficiency of a digital communication system is measured in bit/s/Hz,[2] 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, the spectral efficiency may be measured in bit/symbol, which is equivalent to bits per channel use (bpcu), implying that the net bit rate is divided by the symbol rate (modulation rate) or line code pulse rate.

Link spectral efficiency is typically used to analyze the efficiency of a digital modulation method or line code, sometimes in combination with a forward error correction (FEC) code and other physical layer overhead. In the latter case, a "bit" refers to a user data bit; FEC overhead is always excluded.

The modulation efficiency in bit/s is the gross bit rate (including any error-correcting code) 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.

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 2B symbols/s in view to avoid intersymbol interference. Thus, the spectral efficiency can not exceed 2N (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 2W and an attainable modulation efficiency of 2N (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 2N = 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 2N = 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.

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.

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 edit

In digital wireless networks, the system spectral efficiency or area spectral efficiency is typically measured in (bit/s)/Hz per unit area, in (bit/s)/Hz per cell, or in (bit/s)/Hz per site. It is a measure of the quantity of users or services that can be simultaneously supported by a limited radio frequency bandwidth in a defined geographic area.[1] It may for example be defined as the maximum aggregated throughput or goodput, i.e. summed over all users in the system, divided by the channel bandwidth and by the covered area or number of base station sites. This measure is affected not only by the single-user transmission technique, but also by multiple access schemes and radio resource management techniques utilized. It can be substantially improved by dynamic radio resource management. If it is defined as a measure of the maximum goodput, retransmissions due to co-channel interference and collisions are excluded. Higher-layer protocol overhead (above the media access control sublayer) is normally neglected.

Example 8: In a cellular system based on frequency-division multiple access (FDMA) with a fixed channel allocation (FCA) cellplan using a frequency reuse factor of 1/4, each base station has access to 1/4 of the total available frequency spectrum. Thus, the maximum possible system spectral efficiency in (bit/s)/Hz per site is 1/4 of the link spectral efficiency. Each base station may be divided into 3 cells by means of 3 sector antennas, also known as a 4/12 reuse pattern. Then each cell has access to 1/12 of the available spectrum, and the system spectral efficiency in (bit/s)/Hz per cell or (bit/s)/Hz per sector is 1/12 of the link spectral efficiency.

The system spectral efficiency of a cellular network may also be expressed as the maximum number of simultaneous phone calls per area unit over 1 MHz frequency spectrum in E/MHz per cell, E/MHz per sector, E/MHz per site, or (E/MHz)/m2. This measure is also affected by the source coding (data compression) scheme. It may be used in analog cellular networks as well.

Low link spectral efficiency in (bit/s)/Hz does not necessarily mean that an encoding scheme is inefficient from a system spectral efficiency point of view. As an example, consider Code Division Multiplexed Access (CDMA) spread spectrum, which is not a particularly spectral-efficient encoding scheme when considering a single channel or single user. However, the fact that one can "layer" multiple channels on the same frequency band means that the system spectrum utilization for a multi-channel CDMA system can be very good.

Example 9: In the W-CDMA 3G cellular system, every phone call is compressed to a maximum of 8,500 bit/s (the useful bitrate), and spread out over a 5 MHz wide frequency channel. This corresponds to a link throughput of only 8,500/5,000,000 = 0.0017 (bit/s)/Hz. Let us assume that 100 simultaneous (non-silent) calls are possible in the same cell. Spread spectrum makes it possible to have as low a frequency reuse factor as 1, if each base station is divided into 3 cells by means of 3 directional sector antennas. This corresponds to a system spectrum efficiency of over 1 × 100 × 0.0017 = 0.17 (bit/s)/Hz per site, and 0.17/3 = 0.06 (bit/s)/Hz per cell or sector.

The spectral efficiency can be improved by radio resource management techniques such as efficient fixed or dynamic channel allocation, power control, link adaptation and diversity schemes.

A combined fairness measure and system spectral efficiency measure is the fairly shared spectral efficiency.

Comparison table edit

Examples of predicted numerical spectral efficiency values of some common communication systems can be found in the table below. These results will not be achieved in all systems. Those further from the transmitter will not get this performance.

Spectral efficiency of common communication systems
Service Standard Launched,
year 		Max. net bit rate
per carrier and
spatial stream,
R (Mbit/s) 		Bandwidth
per carrier,
B (MHz) 		Max. link spectral efficiency,
R/B ( bit/(s⋅Hz) ) 		Typical reuse factor, 1/K System spectral efficiency,
R/BK ( bit/(s⋅Hz) ) per site)
SISO MIMO
1G cellular NMT 450 modem 1981 0.0012 0.025 0.45 0.142857 17 0.064
1G cellular AMPS modem 1983 0.0003[3] 0.030 0.001 0.142857 17[4] 0.0015
2G cellular GSM 1991 0.104 0.013 × 8 timeslots = 0.104 0.200 0.2 0.52 0.1111111 19 (13[5] in 1999) 0.17000 0.17[5] (in 1999)
2G cellular D-AMPS 1991 0.039 0.013 × 3 timeslots = 0.039 0.030 1.3 0.1111111 19 (13[5] in 1999) 0.45 0.45[5] (in 1999)
2.75G cellular CDMA2000 1× voice 2000 0.0096 0.0096 per phone call × 22 calls 1.2288 0.0078 per call 1 0.172 (fully loaded)
2.75G cellular GSM + EDGE 2003 0.384 (typ. 0.20) 0.2 1.92 (typ. 1.00) 0.33333 13 0.33[5]
2.75G cellular IS-136HS + EDGE 0.384 (typ. 0.27) 0.200 1.92 (typ. 1.35) 0.33333 13 0.45[5]
3G cellular WCDMA FDD 2001 0.384 5 0.077 1 0.51
3G cellular CDMA2000 1× PD 2002 0.153 1.2288 0.125 1 0.1720 (fully loaded)
3G cellular CDMA2000 1×EV-DO Rev.A 2002 3.072 1.2288 2.5 1 1.3
Fixed WiMAX IEEE 802.16d 2004 96 20 4.8 0.25 14 1.2
3.5G cellular HSDPA 2007 21.1 5 4.22 1 4.22
4G MBWA iBurst HC-SDMA 2005 3.9 0.625 7.3 [6] 1 7.3
4G cellular LTE 2009 81.6 20 4.08 16.32 (4×4) [7] 1 (0.33333 13 at the perimeters[8]) 16.32
4G cellular LTE-Advanced 2013[9] 75 20 3.75 30.00 (8×8) [7] 1 (0.33333 13 at the perimeters[8]) 30
Wi-Fi IEEE 802.11a/g 2003 54 20 2.7 0.33333 13[citation needed] 0.900
Wi-Fi IEEE 802.11n (Wi-Fi 4) 2007 72.2 (up to 150) 20 (up to 40) 3.61 (up to 3.75) Up to 15.0 (4×4, 40 MHz) 0.33333 13[citation needed] 5.0 (4×4, 40 MHz)
Wi-Fi IEEE 802.11ac (Wi-Fi 5) 2012 433.3 (up to 866.7) 80 (up to 160) 5.42 Up to 43.3 (8×8, 160 MHz)[10] 0.33333 13[citation needed] 14.4 (8×8, 160 MHz)
Wi-Fi IEEE 802.11ax (Wi-Fi 6) 2019 600.5 (up to 1201) 80 (up to 160) 7.5 Up to 60 (8×8, 160 MHz) 0.33333 13[citation needed] 20 (8×8, 160 MHz)
WiGig IEEE 802.11ad 2013 6756 2160 3 1[citation needed] 3
Trunked radio system TETRA, low FEC 1998 0.019 4 timeslots = 0.019 (0.029 without FEC)[11][12][13] 0.025 0.8 0.142857 17[14] 0.1
Trunked radio system TETRA II with TEDS, 64-QAM, 150 kHz, low FEC 2011 0.538 4 timeslots = 0.538[11][12][13] 0.150 (scalable to 0.025) 3.6
Digital radio DAB 1995 0.576 to 1.152 1.712 0.34 to 0.67 0.200 15 0.07 to 0.13
Digital radio DAB with SFN 1995 0.576 to 1.152 1.712 0.34 to 0.67 1 0.34 to 0.67
Digital TV DVB-T 1997 31.67 (typ. 24)[15] 8 4.0 (typ. 3.0) 0.143 17[16] 0.57
Digital TV DVB-T with SFN 1996 31.67 (typ. 24)[15] 8 4.0 (typ. 3.0) 1 4.0 (typ. 3.0)
Digital TV DVB-T2 2009 45.5 (typ. 40)[15] 8 5.7 (typ. 5.0) 0.143 17[16] 0.81
Digital TV DVB-T2 with SFN 2009 45.5 (typ. 40)[15] 8 5.7 (typ. 5.0) 1 5.7 (typ. 5.0)
Digital TV DVB-S 1995 33.8 for 5.1 C/N (44.4 for 7.8 C/N)[17] 27.5 1.2 (1.6) 0.250 14[18] 0.3 (0.4)
Digital TV DVB-S2 2005 46 for 5.1 C/N (58.8 for 7.8 C/N)[17] 30 (typ.) 1.5 (2.0) 0.250 14[18] 0.4 (0.5)
Digital TV ATSC with DTx 1996 32 19.39 1.6 1 3.23
Digital TV DVB-H 2007 5.5 to 11 8 0.68 to 1.4 0.200 15 0.14 to 0.28
Digital TV DVB-H with SFN 2007 5.5 to 11 8 0.68 to 1.4 1 0.68 to 1.4
Digital cable TV DVB-C 256-QAM mode 1994 38 6 6.33
Broadband CATV modem DOCSIS 3.1 QAM-4096, 25 kHz OFDM spacing, LDPC 2016 1890[19][20] 192 9.84
Broadband modem ADSL2 downlink 12 0.962 12.47
Broadband modem ADSL2+ downlink 28 2.109 13.59
Telephone modem V.92 downlink 1999 0.056 0.004 14.0

N/A means not applicable.

See also edit

References edit

  1. ^ a b Guowang Miao, Jens Zander, Ki Won Sung, and Ben Slimane, Fundamentals of Mobile Data Networks, Cambridge University Press, ISBN 1107143217, 2016.
  2. ^ Sergio Benedetto and Ezio Biglieri (1999). Principles of Digital Transmission: With Wireless Applications. Springer. ISBN 0-306-45753-9.
  3. ^ C. T. Bhunia, Information Technology Network And Internet, New Age International, 2006, page 26.
  4. ^ Lal Chand Godara, "Handbook of antennas in wireless communications", CRC Press, 2002, ISBN 9780849301247
  5. ^ a b c d e f Anders Furuskär, Jonas Näslund and Håkan Olofsson (1999), "Edge—Enhanced data rates for GSM and TDMA/136 evolution", Ericsson Review no. 1
  6. ^ "KYOCERA's iBurst(TM) System Offers High Capacity, High Performance for the Broadband Era".
  7. ^ a b "4G LTE-Advanced Technology Overview - Keysight (formerly Agilent's Electronic Measurement)". www.keysight.com.
  8. ^ a b Giambene, Giovanni; Ali Yahiya, Tara (1 November 2013). "LTE planning for Soft Frequency Reuse". 2013 IFIP Wireless Days (WD). pp. 1–7. doi:10.1109/WD.2013.6686468. ISBN 978-1-4799-0543-0. S2CID 27200535 – via ResearchGate.
  9. ^ "LTE-Advanced Archives - ExtremeTech". ExtremeTech.
  10. ^ "Whitepaper" (PDF). www.arubanetworks.com.
  11. ^ a b "TETRA vs TETRA2-Basic difference between TETRA and TETRA2". www.rfwireless-world.com.
  12. ^ a b "Application notes" (PDF). cdn.rohde-schwarz.com.
  13. ^ a b "Brochure" (PDF). tetraforum.pl.
  14. ^ "Data". cept.org.
  15. ^ a b c d "Fact sheet" (PDF). www.dvb.org.
  16. ^ a b "List publication" (PDF). mns.ifn.et.tu-dresden.de.
  17. ^ a b "Factsheet" (PDF). www.dvb.org.
  18. ^ a b Christopoulos, Dimitrios; Chatzinotas, Symeon; Zheng, Gan; Grotz, Joël; Ottersten, Björn (4 May 2012). "Linear and nonlinear techniques for multibeam joint processing in satellite communications". EURASIP Journal on Wireless Communications and Networking. 2012 (1). doi:10.1186/1687-1499-2012-162.
  19. ^ "Info" (PDF). scte-sandiego.org.
  20. ^ [1][dead link]

January 01, 1970
spectral, efficiency, spectrum, efficiency, bandwidth, efficiency, refers, information, rate, that, transmitted, over, given, bandwidth, specific, communication, system, measure, efficiently, limited, frequency, spectrum, utilized, physical, layer, protocol, s. Spectral efficiency spectrum efficiency or bandwidth efficiency refers to the information rate that can be transmitted over a given bandwidth in a specific communication system It is a measure of how efficiently a limited frequency spectrum is utilized by the physical layer protocol and sometimes by the medium access control the channel access protocol 1 Contents 1 Link spectral efficiency 2 System spectral efficiency or area spectral efficiency 3 Comparison table 4 See also 5 ReferencesLink spectral efficiency editThe link spectral efficiency of a digital communication system is measured in bit s Hz 2 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 the spectral efficiency may be measured in bit symbol which is equivalent to bits per channel use bpcu implying that the net bit rate is divided by the symbol rate modulation rate or line code pulse rate Link spectral efficiency is typically used to analyze the efficiency of a digital modulation method or line code sometimes in combination with a forward error correction FEC code and other physical layer overhead In the latter case a bit refers to a user data bit FEC overhead is always excluded The modulation efficiency in bit s is the gross bit rate including any error correcting code 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 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 2B symbols s in view to avoid intersymbol interference Thus the spectral efficiency can not exceed 2N 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 2W and an attainable modulation efficiency of 2N 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 2N 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 2N 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 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 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 editIn digital wireless networks the system spectral efficiency or area spectral efficiency is typically measured in bit s Hz per unit area in bit s Hz per cell or in bit s Hz per site It is a measure of the quantity of users or services that can be simultaneously supported by a limited radio frequency bandwidth in a defined geographic area 1 It may for example be defined as the maximum aggregated throughput or goodput i e summed over all users in the system divided by the channel bandwidth and by the covered area or number of base station sites This measure is affected not only by the single user transmission technique but also by multiple access schemes and radio resource management techniques utilized It can be substantially improved by dynamic radio resource management If it is defined as a measure of the maximum goodput retransmissions due to co channel interference and collisions are excluded Higher layer protocol overhead above the media access control sublayer is normally neglected Example 8 In a cellular system based on frequency division multiple access FDMA with a fixed channel allocation FCA cellplan using a frequency reuse factor of 1 4 each base station has access to 1 4 of the total available frequency spectrum Thus the maximum possible system spectral efficiency in bit s Hz per site is 1 4 of the link spectral efficiency Each base station may be divided into 3 cells by means of 3 sector antennas also known as a 4 12 reuse pattern Then each cell has access to 1 12 of the available spectrum and the system spectral efficiency in bit s Hz per cell or bit s Hz per sector is 1 12 of the link spectral efficiency The system spectral efficiency of a cellular network may also be expressed as the maximum number of simultaneous phone calls per area unit over 1 MHz frequency spectrum in E MHz per cell E MHz per sector E MHz per site or E MHz m2 This measure is also affected by the source coding data compression scheme It may be used in analog cellular networks as well Low link spectral efficiency in bit s Hz does not necessarily mean that an encoding scheme is inefficient from a system spectral efficiency point of view As an example consider Code Division Multiplexed Access CDMA spread spectrum which is not a particularly spectral efficient encoding scheme when considering a single channel or single user However the fact that one can layer multiple channels on the same frequency band means that the system spectrum utilization for a multi channel CDMA system can be very good Example 9 In the W CDMA 3G cellular system every phone call is compressed to a maximum of 8 500 bit s the useful bitrate and spread out over a 5 MHz wide frequency channel This corresponds to a link throughput of only 8 500 5 000 000 0 0017 bit s Hz Let us assume that 100 simultaneous non silent calls are possible in the same cell Spread spectrum makes it possible to have as low a frequency reuse factor as 1 if each base station is divided into 3 cells by means of 3 directional sector antennas This corresponds to a system spectrum efficiency of over 1 100 0 0017 0 17 bit s Hz per site and 0 17 3 0 06 bit s Hz per cell or sector The spectral efficiency can be improved by radio resource management techniques such as efficient fixed or dynamic channel allocation power control link adaptation and diversity schemes A combined fairness measure and system spectral efficiency measure is the fairly shared spectral efficiency Comparison table editExamples of predicted numerical spectral efficiency values of some common communication systems can be found in the table below These results will not be achieved in all systems Those further from the transmitter will not get this performance Spectral efficiency of common communication systems Service Standard Launched year Max net bit rate per carrier and spatial stream R Mbit s Bandwidthper carrier B MHz Max link spectral efficiency R B bit s Hz Typical reuse factor 1 K System spectral efficiency R B K bit s Hz per site SISO MIMO 1G cellular NMT 450 modem 1981 0 0012 0 025 0 45 0 142857 1 7 0 064 1G cellular AMPS modem 1983 0 0003 3 0 030 0 001 0 142857 1 7 4 0 0015 2G cellular GSM 1991 0 104 0 013 8 timeslots 0 104 0 200 0 2 0 52 0 1111111 1 9 1 3 5 in 1999 0 17000 0 17 5 in 1999 2G cellular D AMPS 1991 0 039 0 013 3 timeslots 0 039 0 030 1 3 0 1111111 1 9 1 3 5 in 1999 0 45 0 45 5 in 1999 2 75G cellular CDMA2000 1 voice 2000 0 0096 0 0096 per phone call 22 calls 1 2288 0 0078 per call 1 0 172 fully loaded 2 75G cellular GSM EDGE 2003 0 384 typ 0 20 0 2 1 92 typ 1 00 0 33333 1 3 0 33 5 2 75G cellular IS 136HS EDGE 0 384 typ 0 27 0 200 1 92 typ 1 35 0 33333 1 3 0 45 5 3G cellular WCDMA FDD 2001 0 384 5 0 077 1 0 51 3G cellular CDMA2000 1 PD 2002 0 153 1 2288 0 125 1 0 1720 fully loaded 3G cellular CDMA2000 1 EV DO Rev A 2002 3 072 1 2288 2 5 1 1 3 Fixed WiMAX IEEE 802 16d 2004 96 20 4 8 0 25 1 4 1 2 3 5G cellular HSDPA 2007 21 1 5 4 22 1 4 22 4G MBWA iBurst HC SDMA 2005 3 9 0 625 7 3 6 1 7 3 4G cellular LTE 2009 81 6 20 4 08 16 32 4 4 7 1 0 33333 1 3 at the perimeters 8 16 32 4G cellular LTE Advanced 2013 9 75 20 3 75 30 00 8 8 7 1 0 33333 1 3 at the perimeters 8 30 Wi Fi IEEE 802 11a g 2003 54 20 2 7 0 33333 1 3 citation needed 0 900 Wi Fi IEEE 802 11n Wi Fi 4 2007 72 2 up to 150 20 up to 40 3 61 up to 3 75 Up to 15 0 4 4 40 MHz 0 33333 1 3 citation needed 5 0 4 4 40 MHz Wi Fi IEEE 802 11ac Wi Fi 5 2012 433 3 up to 866 7 80 up to 160 5 42 Up to 43 3 8 8 160 MHz 10 0 33333 1 3 citation needed 14 4 8 8 160 MHz Wi Fi IEEE 802 11ax Wi Fi 6 2019 600 5 up to 1201 80 up to 160 7 5 Up to 60 8 8 160 MHz 0 33333 1 3 citation needed 20 8 8 160 MHz WiGig IEEE 802 11ad 2013 6756 2160 3 1 citation needed 3 Trunked radio system TETRA low FEC 1998 0 019 4 timeslots 0 019 0 029 without FEC 11 12 13 0 025 0 8 0 142857 1 7 14 0 1 Trunked radio system TETRA II with TEDS 64 QAM 150 kHz low FEC 2011 0 538 4 timeslots 0 538 11 12 13 0 150 scalable to 0 025 3 6 Digital radio DAB 1995 0 576 to 1 152 1 712 0 34 to 0 67 0 200 1 5 0 07 to 0 13 Digital radio DAB with SFN 1995 0 576 to 1 152 1 712 0 34 to 0 67 1 0 34 to 0 67 Digital TV DVB T 1997 31 67 typ 24 15 8 4 0 typ 3 0 0 143 1 7 16 0 57 Digital TV DVB T with SFN 1996 31 67 typ 24 15 8 4 0 typ 3 0 1 4 0 typ 3 0 Digital TV DVB T2 2009 45 5 typ 40 15 8 5 7 typ 5 0 0 143 1 7 16 0 81 Digital TV DVB T2 with SFN 2009 45 5 typ 40 15 8 5 7 typ 5 0 1 5 7 typ 5 0 Digital TV DVB S 1995 33 8 for 5 1 C N 44 4 for 7 8 C N 17 27 5 1 2 1 6 0 250 1 4 18 0 3 0 4 Digital TV DVB S2 2005 46 for 5 1 C N 58 8 for 7 8 C N 17 30 typ 1 5 2 0 0 250 1 4 18 0 4 0 5 Digital TV ATSC with DTx 1996 32 19 39 1 6 1 3 23 Digital TV DVB H 2007 5 5 to 11 8 0 68 to 1 4 0 200 1 5 0 14 to 0 28 Digital TV DVB H with SFN 2007 5 5 to 11 8 0 68 to 1 4 1 0 68 to 1 4 Digital cable TV DVB C 256 QAM mode 1994 38 6 6 33 Broadband CATV modem DOCSIS 3 1 QAM 4096 25 kHz OFDM spacing LDPC 2016 1890 19 20 192 9 84 Broadband modem ADSL2 downlink 12 0 962 12 47 Broadband modem ADSL2 downlink 28 2 109 13 59 Telephone modem V 92 downlink 1999 0 056 0 004 14 0 N A means not applicable See also editBaud CDMA spectral efficiency Channel capacity Comparison of mobile phone standards Cooper s Law Goodput Network throughput Orders of magnitude bit rate Radio resource management RRM Spatial capacityReferences edit a b Guowang Miao Jens Zander Ki Won Sung and Ben Slimane Fundamentals of Mobile Data Networks Cambridge University Press ISBN 1107143217 2016 Sergio Benedetto and Ezio Biglieri 1999 Principles of Digital Transmission With Wireless Applications Springer ISBN 0 306 45753 9 C T Bhunia Information Technology Network And Internet New Age International 2006 page 26 Lal Chand Godara Handbook of antennas in wireless communications CRC Press 2002 ISBN 9780849301247 a b c d e f Anders Furuskar Jonas Naslund and Hakan Olofsson 1999 Edge Enhanced data rates for GSM and TDMA 136 evolution Ericsson Review no 1 KYOCERA s iBurst TM System Offers High Capacity High Performance for the Broadband Era a b 4G LTE Advanced Technology Overview Keysight formerly Agilent s Electronic Measurement www keysight com a b Giambene Giovanni Ali Yahiya Tara 1 November 2013 LTE planning for Soft Frequency Reuse 2013 IFIP Wireless Days WD pp 1 7 doi 10 1109 WD 2013 6686468 ISBN 978 1 4799 0543 0 S2CID 27200535 via ResearchGate LTE Advanced Archives ExtremeTech ExtremeTech Whitepaper PDF www arubanetworks com a b TETRA vs TETRA2 Basic difference between TETRA and TETRA2 www rfwireless world com a b Application notes PDF cdn rohde schwarz com a b Brochure PDF tetraforum pl Data cept org a b c d Fact sheet PDF www dvb org a b List publication PDF mns ifn et tu dresden de a b Factsheet PDF www dvb org a b Christopoulos Dimitrios Chatzinotas Symeon Zheng Gan Grotz Joel Ottersten Bjorn 4 May 2012 Linear and nonlinear techniques for multibeam joint processing in satellite communications EURASIP Journal on Wireless Communications and Networking 2012 1 doi 10 1186 1687 1499 2012 162 Info PDF scte sandiego org 1 dead link Retrieved from https en wikipedia org w index php title Spectral efficiency amp oldid 1217720721, wikipedia, wiki, book, books, library,

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