Linearity Requirements in LTE-Advanced Mobile Transmitter
Lähteensuo, Toni (2013)
2013
Sähkötekniikan koulutusohjelma
Tieto- ja sähkötekniikan tiedekunta - Faculty of Computing and Electrical Engineering
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Hyväksymispäivämäärä
2013-05-08
Julkaisun pysyvä osoite on
https://urn.fi/URN:NBN:fi:tty-201305221148
https://urn.fi/URN:NBN:fi:tty-201305221148
Tiivistelmä
LTE-Advanced (LTE-A) is an emerging wireless communication system, which builds on the foundation of Long Term Evolution (LTE), adding many unprecedented arrangements in utilization of radio resources. Most notably LTE-A allows allocating non-contiguous resources in frequency domain, which significantly enhances the flexibility of the multiple access scheme. Contiguous and non-contiguous carrier aggregation, both intra- and inter-band, are essential components of LTE-A. However, these features set very high requirements especially for mobile transmitters, which simultaneously should be cheap, small, linear and power efficient.
Linearity in particular is an important aspect because non-contiguous allocation is prone to produce severe intermodulation distortion, which will degrade transmit signal quality and cause interference to users operating on adjacent frequency ranges. Because variety of wireless systems have to coexist and interoperate in the scarce spectrum supply, there are stringent requirements for unwanted spectrum emissions.
There is an inherent trade-off between linearity and power efficiency. Therefore it is significantly difficult to fulfill regulatory spectrum emission requirements with current transmitter technology without sacrificing battery life when operating near the maximum output power. As a compromise LTE-A allows relaxations to maximum output power requirement according to the used submodulation, number of used resource blocks and possible coexistence situations. In practice the transmitter power amplifier (PA) input power is reduced which linearises the PA response. However, this forces the PA to operate less efficiently. This simultaneously constrains using larger constellations and/or higher coding rates because of degraded link budget. Therefore maximum power reduction (MPR) should be minimized.
In this thesis LTE and LTE-A are introduced and the models and effects of transmitter nonlinearity are discussed. Linearity requirements of mobile LTE-A transmitter are evaluated using both simulations and measurements in different transmission scenarios, including LTE and LTE-A releases from 8 to 12. The results of the analysis can be used in development of intelligent radio resource management algorithms, advanced MPR specifications and digital predistortion systems.
Linearity in particular is an important aspect because non-contiguous allocation is prone to produce severe intermodulation distortion, which will degrade transmit signal quality and cause interference to users operating on adjacent frequency ranges. Because variety of wireless systems have to coexist and interoperate in the scarce spectrum supply, there are stringent requirements for unwanted spectrum emissions.
There is an inherent trade-off between linearity and power efficiency. Therefore it is significantly difficult to fulfill regulatory spectrum emission requirements with current transmitter technology without sacrificing battery life when operating near the maximum output power. As a compromise LTE-A allows relaxations to maximum output power requirement according to the used submodulation, number of used resource blocks and possible coexistence situations. In practice the transmitter power amplifier (PA) input power is reduced which linearises the PA response. However, this forces the PA to operate less efficiently. This simultaneously constrains using larger constellations and/or higher coding rates because of degraded link budget. Therefore maximum power reduction (MPR) should be minimized.
In this thesis LTE and LTE-A are introduced and the models and effects of transmitter nonlinearity are discussed. Linearity requirements of mobile LTE-A transmitter are evaluated using both simulations and measurements in different transmission scenarios, including LTE and LTE-A releases from 8 to 12. The results of the analysis can be used in development of intelligent radio resource management algorithms, advanced MPR specifications and digital predistortion systems.