Wise arrangement of antennas is critical in wireless cellular systems for both reductions of co-channel interference (CCI) and increase the quality of service (QoS). In this paper, a novel architecture for antenna arrangement in CDMA wireless cellular systems is presented. In this architecture that we called Microzone, every cell is divided into three (or more) zones and information transmission in downlink channel is done by an antenna which is placed at the outer region of the related zone. Also, the transmitting signal by the mobile station (MS) in uplink channel is received by all the antennas of the related cell. Analytical calculations of the received signal to noise ratio (SIR) and outage probability for both microzone and used architectures show that proposed architecture has better performance in compared with the used architecture. Also, simulation results confirm lower outage probability in uplink channel for microzone architecture.
Frequency reuse in wireless cellular systems based on either code division multiple access (CDMA) or frequency/time division multiple access (FDMA-TDMA) results in co-channel interference (CCI) which is one of the major factors that limits the capacity of cellular systems [
The aim of this section is introducing the used and the microzone architectures. In
are designated by black semi-circles and mobile station (MS) is determined by black triangular. When a MS travels within the cell, its transmitted signal in uplink channel is received by all antennas in a cell and by the use of diversity technique, i.e., maximum ratio combining (MRC); so that an acceptable level of the received signal is achieved. Another advantage of this architecture is remaining a MS in the same cell with same frequency band as long as it travels from one zone to another within the cell. Therefore, unlike sectoring, handoff is not required when the MS travel zone to zone in a cell, and only, the BS switches the signal from one zone to another. In this case, the used antennas are directional and the microzone architecture is configured similar to used architecture (i.e., it has 1, 3, 5 or 7 cells per cluster).
The transmitted signals of all users will be experienced with the channel attenuation that is the most important specification of the radio channel which is shown by and calculated as follows [
where represents the path loss that is the large-scale distance-dependent attenuation in the average signal power. shows shadowing loss that is the mediumscale attenuation, which is caused by reflections, refractions and diffractions of the signal from buildings, trees, and rocks. These result in relatively slow variations in the mean signal power and modeled as a log-normally distributed random variable and known as slow fading. represents the multipath fading or fast fading attenuation, which is the rapid fluctuation in the received signal power that is caused by the constructive and destructive addition of the signals that propagate through different paths with different delays from the transmitter to the receiver. In urban environment the number of significant signal paths is typically much larger than rural areas. This is called the multipath spread, which is the time between the first occurrence of the transmitted signal at the receiver and the last significant reflection of the same signal at the receiver [
where depends on the transmission wavelength, the antenna gain of the transmitter and the antenna gain of the receiver that is given by [
and is the distance between the transmitter and the receiver, is the path loss exponent with typical values ranging from 2 (free space propagation) to 5 (dense urban areas), is a mean zero Gaussian random variable with the standard deviation between 3 to 8 dB, and is assumed to be independent exponentially distributed random variable (In a Rayleigh fading environment, the received signal envelop, has a Rayleigh distribution and its power, , has an exponential distribution). In other words, the received power at the BS from a MS is an exponentially distributed random variable.
Transmitted signals are also polluted by additive white Gaussian noise (AWGN). In CDMA systems, co-channel users’ interference power is much greater than the noise power, and then we use interference power instead of users’ interference plus noise power in the following analysis. Therefore, the ratio of the transmitted signal power to interference power is called signal to interfereence ratio (SIR).
If MS is served byBS, Then the uplink measured SIR forMS at time is calculated as
where and are the transmitted power of user, link gain between MS and BS at time (which is an exponentially distributed random variable) and the noise power which is additive white Gaussian noise (AWGN), respectively. is the number of users that distributed in environment, is the processing gain which equals to that is the total spread spectrum bandwidth occupied by the CDMA signals and is the bit rate transmitted from MS. Note that in a Rayleigh fading channel, is a random variable with a complex distribution, since it has a ratio of an exponential random variable to a sum of exponential random variables with different means. For reliable connection the received SIR should be more than the target value, i.e., [
We assume that the quality of service (QoS) requested is provided when the SIR exceeds a given threshold. The outage probability of theuser at time is given by
Lemma 1: Suppose are independent exponentially distributed random variables with mean, and is a constant, then
Proof: See Appendix 1.
The mean value of the received power in BS from MS at time is given by
Using Equation (6), the measured outage probability is calculated as
In wireless systems, in many situations, there may not be a line-of-sight between the MS and the BS. Therefore, transmitted signals are received from different paths with different delays at the receiver and this causes abrupt increases or decreases in the received signal power. This problem is more troublesome in uplink channel due to the low transmitting power of the MS. In microzone architecture because of using zones in each cell, antenna diversity in the BS is used in uplink channel to overcome this problem. Also, the distance between each pair of antennas is at least several times greater than the transmitted signal wavelength, so that the signal transmission paths would stay independent from each other. Then, if the probability of a received signal from an antenna falls below the threshold, equals, the probability that all the received signals by antennas simultaneously falls below the threshold, would be, which is considerably smaller than. If MS is served by BS includes an antenna in each zone. Then the uplink measured SIR from antenna at time is calculated as
The received signals by all antennas are combined using MRC algorithm [
where is the weighting factor related to the antenna at time and is the received SIR of the antenna related to zone and the output of the diversity combiner, , is calculated as
Equation (10) shows that using diversity technique, greater value of the received SIR is achievable and possible in microzone architecture.
We assume that the quality of service (QoS) requested is provided when the output of the diversity combiner, exceeds a given threshold. The outage probability of the user at time is given by
Microzone architecture has some advantages that are listed as follows.
1) The received SIR is increased by the use of diversity technique;
2) If users uniformly distributed in a cell then a large number of them are distributed at the regions near to antennas of a cell in compared with the used architecture. Therefore, by the use of microzone architecture, the received SIR is also increased;
3) An increase in the received SIR will decrease the outage probability and finally, network capacity and performance will be increased;
4) Handoff is not required when the MS travel in a cell.
Because of using diversity technique, antenna arrangement, and above mentioned reasons
that is shown and confirmed by the simulation results in the next section.
In this section, the simulations are done for used and microzone architectures to investigate the system performance. Based on
mean of zero and a standard deviation of. Here we ignore the effect of Doppler frequency. The path loss exponent equals to 4.