一种时间高效的易于实现的多标签射频识别技术

多标签碰撞问题严重影响射频识别RFID系统的识别效率.在研究子帧观测机制的基础上,针对常规动态帧时隙Aloha多标签防碰撞算法存在的复杂度高、时间效率低等问题,提出了一种基于子帧的动态帧时隙Aloha算法,其在识别过程中采取设定的子帧观测,运用空闲与碰撞时隙数的关系估计剩余标签数,再依据预估的结果优化设置新的帧长,显著提升了大容量多标签RFID系统的识别效率.该算法的运算复杂度低、计算量小,易于在常规RFID读写器中实现,工程应用前景广阔.仿真结果表明：同传统的Aloha类防碰撞算法相比,提出的算法具有复杂度低、稳定好、识别效率高等优势.     

一种基于碰撞位指示的射频识别标签防碰撞算法

多标签碰撞是射频识别(RFID)技术在推广应用中必须克服的一个问题。针对目前RFID标签防碰撞算法存在识别效率低的不足,该文提出一种基于碰撞位指示的RFID标签防碰撞的碰撞位指示算法(CBIA)。通过跟踪待识别标签的碰撞位,采用碰撞位编解码技术,对待识别标签进行重复分组,直到所有标签都被正确识别。算法通过确定性分组,避免了空闲时隙的产生。仿真结果表明,采用CBIA算法的多标签识别系统,吞吐率可以达到每时隙0.7个标签,CBIA算法识别效率优于优化查询跟踪树算法(OQTT)和碰撞跟踪树算法(CTTA)算法。     

改进型帧时隙ALOHA防碰撞算法研究

为进一步提高RFID系统中电子标签防碰撞算法的识别效率,对帧时隙ALOHA防碰撞算法的性能进行分析,提出一种结合精确标签估计和二进制搜索的改进型帧时隙ALOHA算法.将识别过程分为标签估计和标签识别两个阶段,在标签估计算法中引入碰撞概率上、下限参数,并精确估计标签数量对初始帧时隙大小进行优化;在标签识别阶段,利用二进制搜索算法对时隙内的碰撞标签进行快速识别.通过对识别过程进行仿真结果表明:改进的算法改善了防碰撞性能,提高了RFID系统的标签识别效率.     

分组自适应分配时隙的RFID防碰撞算法研究

为了解决射频识别(Radio Frequency IDentification,RFID)系统中的多标签防碰撞问题,在分析帧时隙ALOHA算法的基础上,提出一种基于分组自适应分配时隙的RFID防碰撞算法(GAAS).首先让阅读器对标签随机所选的时隙进行扫描统计,并将其发送给每一个标签,标签再进行相应地时隙调整,使阅读器跳过空闲时隙和碰撞时隙,自适应地分配有效时隙,进而对标签进行快速识别.当未识别标签数比较大时,算法采用分组以及动态调整帧长等策略,以减少时隙处理的时间.仿真结果表明:GAAS算法提高了系统的识别效率和稳定性,降低了传输开销.特别是当标签数超过1000时,该算法的吞吐率仍保持在71%以上,比传统的帧时隙ALOHA-256算法和分组动态帧时隙ALOHA算法的系统效率分别提高了300%和97.2%.     

自调整混合树RFID多标签防碰撞算法

在RFID系统中,阅读器读取标签的效率与解决标签发生碰撞的方法密切相关.目前采用多叉树查询是一种较好的多标签防碰撞方法.它能减少碰撞时隙,再通过额外的查询来减少空闲时隙.但额外的查询也增加了新的开销.本文提出了一个自调整混合树RFID多标签防碰撞算法,该算法根据最高两个碰撞位的特征,在不增加额外查询的条件下,自调整搜索树的叉数,从而避免了一些碰撞时隙和空闲时隙.通过对算法的性能分析和仿真结果可以看到,自调整混合树RFID多标签防碰撞算法具有较少的时间复杂度和通信复杂度,识别效率也明显高于其他多叉树算法.     

改进型动态时隙冲突跟踪树标签防碰撞算法

射频识别RFID(Radio Frequency Identification)系统内的读卡器在识别大数量标签时常因信号的碰撞而导致系统识别效率降低.动态时隙冲突跟踪树算法DSCTTA(Dynamic Slots Collision Tracking Tree Algorithm)采用动态时隙应答机制可减少前缀开销和迭代开销,但会产生大量空闲时隙.本文将DSCTTA和比特转换方式(BCM)相结合,得到改进型动态时隙冲突跟踪树标签防碰撞算法(IDSCTTA)以防止标签冲突,加快标签识别速度.理论分析及仿真结果表明,IDSCTTA不仅具有DSCTTA的全部优点,而且能够有效地减小识别时延和提高时隙效率,并且标签数目越大,算法性能越优越.     

基于标签识别码分组的连续识别防碰撞算法研究

标签碰撞增加了射频识别(RFID)系统的时间开销和无源标签的能量消耗,降低了识别速率.该文提出了一种适用于标签识别码连续的防碰撞算法--UIG算法,该算法首先根据公司编码和产品编码将所有标签分组,再由产品序列号的碰撞信息生成每组的两个初始标签识别码.最后,通过对初始标签识别码分别连续减1和加1识别出所有标签.性能分析和...     

基于标签截断的分组防碰撞算法

防碰撞算法是RFID标签识别的核心算法之一。文章在EPC Gen2协议的基础上,提出一种新的基于标签截断的分组防碰撞算法。实验表明,该算法有效缩小了在读写器读取范围内所有标签的读取总时隙,读取标签的效率得到了明显提高。     

位屏蔽多叉树搜索射频识别防碰撞算法

针对RFID树型防碰撞算法中时隙数多、数据通行量大等问题,提出了一种改进的多叉树防碰撞算法,阅读器准确检测碰撞位并向标签反馈碰撞位信息,标签对阅读器已知的ID位进行屏蔽,把ID号转换成连续碰撞的序列号.阅读器利用屏蔽位信息和标签返回的碰撞位编码信息,对标签进行分层分类搜索.通过对标签ID进行屏蔽,阅读器和标签间仅发送对方不知道的碰撞位信息.该算法减少了碰撞时隙和识别时隙,避免了空闲时隙,减少了阅读器和标签间的数据通信量.理论分析和仿真结果表明,该算法减少了系统的时隙总数和数据通信量,提高了阅读器的识别效率.     

RFID技术在物流中的应用与研究

无线射频识别技术（RFID）是一种新的自动识别技术,其独有的优势对物流起到很重要的作用并会取代条形码。基于这些因素,首先介绍了RFID技术的原理、特点;然后分析RFID技术和其防碰撞算法怎么在物流领域中进行应用,并对RFID防碰撞算法进行仿真,主要分析时隙ALOHA算法中的时隙数对标签识别率的问题,使得到的数据能在物流应用中提供参考;最后指出制约RFID技术发展的因素和其应用前景。     

Instant collision resolution for tag identification in RFID networks

In this paper, we approach the problem of identifying a set of objects in an RFID network. We propose a modified version of Slotted Aloha protocol to reduce the number of transmission collisions. All tags select a slot to transmit their ID by generating a random number. If there is a collision in a slot, the reader broadcasts the next identification request only to tags which collided in that slot. Besides, we present an extensive comparative evaluation of collision resolution protocols for tag identification problem in RFID networks. After a quick survey of the best performing RFID tag identification protocols, both deterministic and probabilistic, we present the outcome of intensive simulation experiments set up to evaluate several metrics, such as the total delay of identification process and the bit complexity of reader and tags. The last metric is strictly related to energy constraints required by an RFID system. The experiments point out that our protocol outperform all the other protocols in most cases, and matches them in the others.     

基于CDMA技术的新型防碰撞算法

标签碰撞是射频识别（RFID）技术的常见问题,该问题影响了RFID系统通信过程中数据传输的完整性.在分析已有防碰撞方法的基础上,根据帧时隙分组ALOHA算法,结合码分多址技术,提出了新型的标签防碰撞算法.该算法能够有效减小标签之间的碰撞概率,缩短读写器操作时间,提高吞吐率,很适合应用于具有较大数量标签的RFID系统中.     

A new anti‐collision protocol based on information of collided tags in RFID systems

Radio frequency identification (RFID) technology has recently become an integral part of a wide range of applications. One of the challenges in RFID systems is the tag anti‐collision issue, for which several anti‐collision tag identification protocols have been proposed. This paper proposes a novel slotted ALOHA‐based RFID tag anti‐collision algorithm which can be employed for tag identification. The main idea of this algorithm is to use the information available in collision slots, called collided data, to identify tags uniquely. For this purpose, the collision slots that include only two tags are selected. Then, the non‐conflict bits in these slots are used to possibly identifying the tags. Because in the proposed algorithm readers use both single slots and also the collision slots for tag identification, the performance is increased significantly compared with other protocols. Results of the study indicate that in the proposed algorithm, the optimal frame size for an individual tag number is equal to the half of tags number and the efficiency of the proposed protocol is improved to about 73%. Copyright © 2015 John Wiley & Sons, Ltd.     

Novel tag estimation method by use of Manchester coding in RFID systems

Radio frequency identification suffers from tag collision issue. ALOHA‐based algorithms are useful and practical groups of tag anti‐collision algorithm among others. Some standards such as EPCglobal Class‐1 Generation‐2 use some kind of dynamic framed slotted ALOHA (DFSA) to cope with tag collision. DFSA efficiency depends on estimating the number of unidentified tags in each identification cycle accurately. So tag estimation is one of the challenging issues in DFSA. In this paper, we use Manchester coding to compute the lower bound of collided tags in a frame and then add α as an additional value to computed value according to the difference between optimal number of collision slots and calculated number of collision slots. Then, we evaluate and compare our method with other proposed methods.     

Adaptive binary splitting for efficient RFID tag anti-collision

Tag collision arbitration for passive RFID tags is a significant issue for fast tag identification. This letter presents a novel tag anti-collision scheme called adaptive binary splitting (ABS). For reducing collisions, ABS assigns distinct timeslots to tags by using information obtained from the last identification process. Our performance evaluation shows that ABS outperforms other tree based tag anti-collision protocols.     

A Collision Arbitration Protocol Based on Specific Selection Function

Fast and eff ective identifications of a large number of items are required in many Radio-frequency identification (RFID) applications. Simultaneous responses from multiple tags are corrupted by collisions and thus re-sult in low identification efficiency. To address the prob-lem of low identification eifficiency, many existing tag anti-collision algorithms try to schedule the identification pro-cess to avoid collisions. A novel anti-collision scheme based on specific selection function is presented, in which tags pick a slot according to a selection function instead of be-ing randomly assigned to slots within a frame. If collision occurs, the reader sends the custom command SETBM ac-cording to the collision information. When probed by the SETBM, the tags apply the selection function to its partial ID and send the mapped result to the reader. According to the mapped result, the reader assigns the time slot to the tags. All tags collided in the same slot will be identified by the tree traversal scheme. Compared to the most of exist-ing anti-collision algorithms, simulation results show that our proposed algorithm can achieve better performance in terms of identification efficiency, time efficiency, and en-ergy consumption.     

Accurate tag estimation for dynamic framed-slotted ALOHA in RFID systems

Dynamic Framed-Slotted ALOHA (DFSA) is one of the most popular algorithms to resolve tag collision in RFID systems. In DFSA, it is widely known that the optimal performance is achieved when the frame size is equal to the number of tags. So, a reader dynamically adjusts the next frame size according to the current number of tags. Thus it is important to estimate the number of tags accurately. In this paper, we propose a novel tag estimation method for DFSA. We compare the performance of the proposed method with those of other existing methods. And, simulation results show that our scheme improves the accuracy of tag estimation and the speed of tag identification.     

一种减少通信复杂度的RFID搜索树防碰撞算法

针对射频识别搜索树防碰撞算法中通信数据量大、识别时延长等问题,提出了一种减少通信复杂度的防碰撞算法.在标签中引入前缀长度寄存器和响应标志寄存器,在阅读器堆栈区存储前缀个数信息,阅读器通过发送前缀长度信息,对标签进行分类搜索,阅读器和标签不再发送对方已经识别的序列号,有效减少了通信数据量.仿真结果表明,与传统的二叉树搜索防碰撞算法相比,该算法可明显减少系统通信复杂度,提高标签的搜索速率.     

Tree-based backoff protocol for fast RFID tag identification

This paper proposes a tree-based backoff (TBB) protocol that reduces the number of iterations implemented in the procedure of tag collision arbitration in radio frequency identification (RFID) systems. This is achieved by employing the following mechanisms: one is send the request command iteratively to all tags in the interrogation zone until a single tag is identified. The other is backward to the parent node instead of root node to obtain the request parameters and send the request command again until all tags are identified. Compared with the traditional tree-based protocol, on average, simulated results show that the TBB protocol reduces the number of the iterations by 72.3% and the identification delay by 58.6% and achieves the goal of fast tag identification.