2012 International Symposium on Telecommunication Technologies 2012
DOI: 10.1109/istt.2012.6481597
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Energy efficiency of LTE macro base station

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Cited by 15 publications
(11 citation statements)
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“…The cell radius for each type of BS is calculated based on a cell coverage requirement of C D 95% by setting the transmit powers for MeNB, MieNB and PeNB to 46, 35 and 30 dBm, respectively. Our previous work in [20] has demonstrated the influence of BW on EE. It is shown that EE increases significantly as the BW increases.…”
Section: Numerical Results and Discussionmentioning
confidence: 99%
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“…The cell radius for each type of BS is calculated based on a cell coverage requirement of C D 95% by setting the transmit powers for MeNB, MieNB and PeNB to 46, 35 and 30 dBm, respectively. Our previous work in [20] has demonstrated the influence of BW on EE. It is shown that EE increases significantly as the BW increases.…”
Section: Numerical Results and Discussionmentioning
confidence: 99%
“…The cell coverage area C , which is the fraction of cell area where the received power of user terminal is above P min , can be written as C MathClass-rel= Q(a) MathClass-bin+normalexp ()2 MathClass-bin−2ab b2 Q ()2 MathClass-bin−ab b where the Q‐function is defined as the probability that a Gaussian random variable X with mean 0 and variance 1 is greater than z Q(z) MathClass-rel= prob(X ⩾ z) MathClass-rel= 1 2πfalsefalseMathClass-op∫zMathClass-rel∞normalexp ()MathClass-bin−x2 2 dx and a MathClass-rel= Pnormalmin MathClass-bin−Pitalicrx(Rg) σΨdB1emquadMathClass-punc,1emquadb MathClass-rel= 10αnormallog10(e) σΨdB where α is the PL exponent and σ ψdB is the standard deviation of shadow fading, whereas P rx ( R g ) represents the received power at cell edge ( R g ). Hence, the coverage area of a cell is a function of receiver sensitivity P min , carrier frequency f , transmitted power P tx , PL exponent α and shadowing standard deviation σ ψdB . By limiting the coverage area to a certain size, the network performance in terms of achievable data rates and efficiencies within each BS can be estimated.…”
Section: Network Modelsmentioning
confidence: 99%
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“…An investigation on the impact of these factors on EE has been presented in [46]. Authors of [116] presented the tradeoffs between gains in cell throughput and reception technologies and the increased energy consumption that they induced in cellular BSs. The EE in term of ECR of MIMO schemes applicable for 3GPP LTE is analyzed on different antenna configuration in [89] and [117].…”
Section: Bs's Energy-awarenessmentioning
confidence: 99%
“…Menghitung sensitifitas penerima (sensitivity receiver) Sensitifitas penerima (Pmin), seperti ditunjukkan pada formula (1), adalah daya minimum yang diterima dimana persyaratan throughput masih terpenuhi (Abdulkafi et al, 2012) atau rata-rata kuat sinyal minimum yang ditangkap antena dengan SINR yang cukup untuk skema modulasi yang digunakan untuk memenuhi persyaratan throughput minimum sebesar 95% dari nilai throughput maksimum yang mungkin (Belhouchet & Ebdelli, 2010 Dengan mengasumsikan model propagasi tertentu maka akan diperoleh radius cakupan dari sebuah BS berdasarkan rugi-rugi lintasan maksimum yang diperoleh dari perhitungan sebelumnya. Model propagasi dapat diklasifikasikan menjadi model empiris dan model deterministik (Singh, 2012 …”
Section: Coverage Analysis (Analisis Cakupan)unclassified