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We revisit the problem of missing tag identification in RFID networks by making three contributions. Firstly, we quantitatively compare and gauge the existing propositions spanning over a decade on missing tag identification. We show that the expected execution time of the best solution in the literature is (N+ (1-) ² (1-) ² ²), where and are parameters quantifying the required identification accuracy, N denotes the number of tags in the system, among which N tags are missing. Secondly, we analytically establish the expected execution time lower-bound for any missing tag identification algorithm as (N N+ (1-) ² (1-) ²² (1-) (1-) {}), thus setting the theoretical performance limit. Thirdly, we develop two novel missing tag identification algorithms with the expected execution time of (N NN+ (1-) ² (1-) ² ²), reducing the time overhead by a factor of up to N over the best algorithm in the literature. The key technicality in our first algorithm is a novel data structure termed as collision-partition tree (CPT), built on a subset of bits in tag pseudo-IDs, leading to a more balanced tree structure and reducing the time complexity in parsing the entire tree. To further improve time efficiency, our second algorithm integrates multiple CPTs to form a collision-partition forest (CPF), reducing both the number of slots and the quantity of information broadcasting.
Liu et al. (Tue,) studied this question.