cdma2000 1x语音和数据业务并发时无线信道容量的计算

1前言 影响CDMA系统容量的因素很多,尤其是其网络覆盖与有效容量会相互牵制,呈现出“软容量”的特性,增加了CDMA系统容量分析的复杂度。CDMA系统是自干扰系统,当反向链路上新增加终端的最大发射功率不足以使基站克服来自其他终端的干扰时,系统就达到了反向容量的极限。     

CDMA网络中多媒体业务的接入控制

从码分多址(CDMA)系统的特点出发，采用多维马尔可夫过程来分析多媒体业务共存时基于干扰水平的接入控制策略，得到在小区容量可变情况下的系统性能。文中考虑到切换用户的优先级以及不同类型用户的不同QoS要求，还在系统中设置了多级接入门限，从而实现在扩大系统容量的同时，又力求保证系统已有的链路质量，实现接入控制的目的。     

可变扩频增益CDMA系统中功率速率的联合控制

在提供多媒体业务的3G系统中,不同的业务传输速率在传输过程中是可变的,可用功率速率联合控制来处理第三代移动通信系统中的无线资源分配问题.在可变扩频增益CDMA系统中,用户根据其无线环境确定其传输速率和发射功率,基于博弈论提出了使用户净吞吐量最大化的功率速率联合控制方案.对信干比要求不严格的业务,可依照一定的概率来决定是否调整用户数据传输速率,仿真表明,这样可使用户的传输速率进一步提高,更有效地利用系统资源.     

浅析CDMA2000容量优化

CDMA系统是自干扰、容量受限的系统。在CDMA2000系统中,空中接口的容量与业务的Eb/Io、增益处理、其他小区的干扰、基站发射功率和信道码的数量相关,也就是说,CDMA的容量是软容量。容量、网络性能、质量永远是相互矛盾的关系。只有对网络容量进行有效优化,才能更好地平衡三者关系。文章介绍CDMA2000容量优化的重要性,说明容量优化的原理及影响容量的因素,分析容量优化可能采用的方法,最后进行评估。     

多载波CDMA容量的研究

该文对多载波CDMA容量规划进行了详细的理论和数学分析,推导出多载波CDMA上下行链路的容量的表达式,利用拉格朗日乘数求极值的方法,分别得到多载波CDMA话音和数据业务上下行链路最大容量;同时得出一个非常重要的结论:只有当即基站最大发射功率平均分配给每个子载波时,多载波CDMA系统才能获得最大的容量。该文还对影响容量的因素进行了仿真,各业务的容量随平均路径损耗的增加急剧下降。由此揭示了容量和覆盖的内在关系:容量和覆盖是相互制约的一对矛盾,容量的增加就意味着覆盖的减小,反之亦然。无论上下行链路,当功率达到一定程度时,再通过增大功率来提高容量并不是行之有效的方法。最后,通过对GSM,WCDMA,多载波CDMA 3个系统容量的比较,得出多载波CDMA下行链路频谱效率为WCDMA频谱效率的1.7倍,GSM 的2.7倍;上行链路频谱效率为WCDMA频谱效率的2.1倍,GSM 的2.4倍的结论。     

简析CDMA蜂窝系统Erl容量

蜂窝网采用空间频率再用技术大大地缓解了频谱资源有限与用户不断增长之间的矛盾.其中CDMA蜂窝网的容量最大,而且还具有软容量特性.但是由于CDMA是自干扰系统,它在直接应用Erl B定理之前受空间Erl容量概念的制约.本篇文章简要分析了在CDMA系统中计算Erl容量的方法,并涉及了一些针对这一CDMA特有概念的优化工作.     

UWB设备对CDMA系统下行链路容量的影响

本文研究了超宽带(UWB)设备对CDMA系统下行链路容量的影响.文中首先建立了UWB设备的分布模型,针对已有的WCDMA系统模型,应用计算机仿真,得出CDMA系统中加入UWB设备后的系统容量与UWB设备发射功率、分布密度的关系.     

CDMA2000中的功率控制及容量仿真

在码分多址(CDMA)系统中,在不影响通话质量的前提下,要使得系统容量最大化需要采用功率控制技术.功率控制的主要方法是通过降低每个移动台和基站的发射功率使得系统中干扰最小化.在建立模型的基础上,文章分别对单小区和多小区CDMA系统的系统容量进行了理论推导,并采用19个小区的仿真模型对系统容量进行了仿真.在将仿真得出的结果与理论推导值比较后,得出结论:功率控制的偏差直接导致系统容量的下降,因此研究出更好的功率控制算法对于提高系统容量至关重要.     

一种CDMA网络多业务的呼叫允许控制算法

现今无线网络中的多媒体业务具有很大需求。该文对多业务CDMA通信系统容量进行分析,引入有效带宽概念,提出一种呼叫允许控制资源分配优化算法(CAC-RA)。此算法将多媒体业务分为实时业务和非实时业务,通过对自适应实时业务采用马尔科夫模型,对非实时业务采用排队模型,将两模型合并生成的的利益函数采用非线性规划,使呼叫允许控制、切换策略和资源分配问题同时得到解决。实验数据显示CAC-RA算法实现了合理的资源利用和最大的利益值,能较好地适应多业务CDMA网络。     

CDMA系统下行链路容量研究

本文从基本的码分多址(CDMA)理论出发,根据WCDMA系统建立系统模型,从基站发射功率受限和小区间的相互干扰与影响的角度入手,结合计算机仿真,对CDMA系统的下行链路的容量特性作了分析与计算,分析了传播环境、小区半径、切换门限等参数对下行容量的影响,并使用计算机仿真对分析结果作了验证.对比表明,该分析结果与计算机仿真所得结果吻合的较好,可以作为分析、设计CDMA网络的基础.     

Multirate optical fast frequency hopping CDMA system using powercontrol

This paper addresses the problem of real-time multimedia transmission in fiber-optic networks using code division multiple access (CDMA). We present a multirate optical fast frequency hopping CDMA (OFFH-CDMA) system architecture using fiber Bragg gratings (FBGs). In addition, we argue that, in multimedia applications, different services have different quality of service (QoS) requirements; hence, the user only needs to use the minimum required power to transmit the signal, such that the required signal-to-interference ratio (SIR) is met. We show that a variable bit rate optical communication system with variable QoS can be implemented by way of power control with great efficiency. Present-day multirate optical CDMA systems concentrate on finding the code structure that supports a variable rate system, neglecting the importance of the transmission power of active users on the multiple access interference (MAI) and, therefore, on the system capacity. We assign different power levels to each rate through a power control algorithm using variable optical attenuators, which minimizes the interference and, at the same time, provides variable QoS constraints for different traffic types. Although we are using a code family that preserves good correlation properties between codes of different lengths, simulations show a great improvement in the system capacity when power control is used     

CDMA systems in fading channels: admissibility, network capacity,and power control

We study the admissibility and network capacity of imperfect power-controlled code-division multiple access (CDMA) systems with linear receivers in fading environments. In a CDMA system, a set of users is admissible if their simultaneous transmission does not result in violation of any of their quality-of-service (QoS) requirements; the network capacity is the maximum number of admissible users. We consider a single-cell imperfect power-controlled CDMA system, assuming known received power distributions. We identify the network capacities of single-class systems with matched-filter (MF) receivers for both the deterministic and random signature cases. We also characterize the network capacity of single-class systems with linear minimum-mean-square-error (MMSE) receivers for the deterministic signature case. The network capacities can be expressed uniquely in terms of the users' signal-to-interference ratio (SIR) requirements and received power distributions. For multiple-class systems equipped with MF receivers, we find a necessary and sufficient condition on the admissibility for the random signature case, but only a sufficient condition for the deterministic signature case. We also introduce the notions of effective target SIR and effective bandwidth, which are useful in determining the admissibility and hence network capacity of an imperfect power-controlled system     

QoS based fair resource allocation in multi-cell TD/CDMA communication systems

Abstract-In a wireless multimedia code division multiple access (CDMA) system, the resources in terms of transmission rate and power should be efficiently distributed to each user to guarantee its quality-of-service (QoS) requirements. In, this paper, a resource allocation algorithm which combines packet scheduling and power assignment is proposed to achieve efficient resource utilization under QoS constraints. The packet scheduling is based on the fair packet loss sharing (FPLS) principle, and the power assignment is determined by the received power limited (RPL) scheme. The basic idea of FPLS is to schedule the transmission of multimedia packets in such a way that, all the users have a fair share of packet loss according to their QoS requirements, which maximizes the number of the served users with QoS satisfaction. The RPL scheme minimizes the received power for each packet. Given the propagation path loss, it in turn minimizes the transmitted power as well. The intercell interference from the scheduled packets is also limited in order to increase the system capacity.     

Capacity Analysis for Connection Admission Control in Indoor Multimedia CDMA Wireless Communications

In this paper, the capacity analysis for connection admission control is presented for the reverse-link transmission of a packetized indoor multimedia wireless communication system using direct sequence code division multiple access (DS/CDMA). Since CDMA is interference limited, the signal-to-interference-plus-noise ratio criterion is used to check if there is enough system resources (i.e., the CDMA channels and received signal power) for each new connection request. Taking into account the stochastical nature of multimedia traffic, the effective bit rate is used to characterize the resources required by each mobile user and a linear approximation is then used to find the total resources required by all the mobile users already admitted to the system and the new connection request. Transmission errors due to both base station buffer overflow and wireless channel impairments are considered. The capacity of multimedia traffic is determined in such a way that the utilization of the system resources is maximized and, at the same time, the required transmission bit error rate and transmission delay of all users admitted to the system are guaranteed. Computer simulation results are given to demonstrate the performance of the proposed method for capacity analysis.     

An FDD wideband CDMA MAC protocol with minimum-power allocation and GPS-scheduling for wireless wide area multimedia networks

A frequency division duplex (FDD) wideband code division multiple access (CDMA) medium access control (MAC) protocol is developed for wireless wide area multimedia networks. In order to reach the maximum system capacity and guarantee the heterogeneous bit error rates (BERs) of multimedia traffic, a minimum-power allocation algorithm is first derived, where both multicode (MC) and orthogonal variable spreading factor (OVSF) transmissions are assumed. Based on the minimum-power allocation algorithm, a multimedia wideband CDMA generalized processor sharing (GPS) scheduling scheme is proposed. It provides fair queueing to multimedia traffic with different QoS constraints. It also takes into account the limited number of code channels for each user and the variable system capacity due to interference experienced by users in a CDMA network. To control the admission of real-time connections, a connection admission control (CAC) scheme is proposed, in which the effective bandwidth admission region is derived based on the minimum-power allocation algorithm. With the proposed resource management algorithms, the MAC protocol significantly increases system throughput, guarantees BER, and improves QoS metrics of multimedia traffic.     

Optimal sequences and sum capacity of symbol asynchronous CDMA systems

The optimal signature sequences that maximize the sum capacity of a direct sequence code-division multiple-access (CDMA) system are characterized in the general case of symbol delay profile and user power constraints. It is shown that the optimal sum capacity of the symbol asynchronous system equals that of the symbol synchronous system with the same user power constraints. With the optimal signature sequence set, the maximum sum capacity is achieved with white Gaussian input signals. The existence of the optimal signature sequence set is proved by the proposal of an explicit construction method for arbitrary user delay profiles and power constraints.     

Energy Efficiency-Delay Tradeoffs in CDMA Networks: A Game-Theoretic Approach

A game-theoretic approach for studying energy efficiency-delay tradeoffs in multiple-access networks is proposed. Focusing on the uplink of a code-division multiple-access (CDMA) network, a noncooperative game is considered in which each user seeks to choose a transmit power that maximizes its own utility while satisfying its (transmission) delay requirements. The utility function measures the number of reliable bits transmitted per joule of energy and the user's delay constraint is modeled as an upper bound on the delay outage probability. The Nash equilibrium for the proposed game is derived, and its existence and uniqueness are proved. Using a large-system analysis, explicit expressions for the utilities achieved at equilibrium are obtained for the matched filter, decorrelating and (linear) minimum-mean-square-error (MMSE) multiuser detectors. The effects of delay quality-of-service (QoS) constraints on the users' utilities (in bits per joule) and network capacity (i.e., the maximum number of users that can be supported) are quantified. Using the proposed framework, the tradeoffs between energy efficiency and delay are quantified in a competitive multiuser setting.     

A wireless multimedia CDMA system based on transmission powercontrol

This paper proposes a wireless multimedia code division multiple access (CDMA) system based on transmission power control. When we transmit multimedia information (i.e., speech, image, and data), differences in information rate, traffic performance, and required quality should be taken into account. The wireless CDMA system can achieve a flexible balance if transmission power distribution is controlled by using channel measurement information, i.e., traffic. In this paper, the optimal control of transmission power is derived by linear programming and nonlinear programming. Numerical results using a LAN demonstrate that the proposed method can satisfy the required quality     

A New MAC Protocol Ensuring the Multimedia Traffic QoS for CDMA Networks

This paper describes the CDMAC, a new Medium Access Control (MAC)protocol for multimedia traffic in CDMA wireless networks. Theprotocol intends to extract the maximum capacity and flexibilityout of the CDMA scheme and at the same time guarantee the expectedQoS of different service types. CDMAC is able to maintain QoSrequirements thanks to the shaping, policing and trafficdifferentiation performed by the scheduler. Moreover, an iterativealgorithm, applied at the beginning of each frame, is used to findthe optimal power vector for all mobiles present in the system,which maximize the system capacity. The basic constraint of thecapacity maximization process is that the BER QoS of eachconnection should be fulfilled. Finally a distributedimplementation, feasible in a practical scenario, is presented.     

Uplink capacity optimization by power allocation for multimedia CDMA networks with imperfect power control

A closed-form capacity quasi-optimal power allocation scheme is presented for the uplink of multimedia code-division multiple-access (CDMA) systems with randomized received signal-to-interference ratio (SIR) resulted from the errors of power control. The optimality in capacity comes from that this scheme provides class-dependent SIR margins subject to the constraint of differentiated outage requirements. The statistics of signal under imperfect power control is modeled as lognormal random variable. The objective of capacity maximization is formulated as the minimization of total average received powers since the capacity of a CDMA system is interference limited. Under this model, we first derive the necessary conditions that a capacity-optimal power allocation should satisfy. By using conservative bounds, we provide a closed-form approximate solution to this optimization problem. This approximate solution provides nearly the same admissible region for multimedia traffic under imperfect power control as the accurate solution (the optimal one) does. The closed-form quasi-optimal power allocation scheme proposed in this paper is just based on this approximate solution. By numerical example we verify our analysis and show that great capacity gain (e.g., 92% as a maximum in the example) can be achieved by our scheme over its counterpart.