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Pneumothorax development can cause precipitous deterioration in ICU patients, therefore quick and accurate detection is vital. Portable chest radiography is commonly performed to exclude pneumothoraces but is hampered by supine patient position and overlying internal and external material. Also, the initial evaluation of the chest radiograph may be performed by a relatively inexperienced physician. Therefore, a tool that could significantly improve pneumothorax detection on portable radiography would be helpful in patient care. The aim of this study was to evaluate the clinical utility of novel enhancement software for pneumothorax detection in readers with varied clinical experience of detecting/excluding pneumothoraces on portable chest radiographs in ICU patients. 206 portable ICU chest radiographs, 103 with pneumothoraces, were processed with and without enhancement software and reviewed by 5 readers who varied in reading experience. Images were grouped for different complexity levels. The mean AUC for pneumothorax detection increased for 4/5 readers from 0.846-0.957 to 0.88-0.971 with a largest improvement for the reader with least experience. No significant change was noted for the reader with the longest reading experience. The image complexity had no impact on the interpretation result. Pneumothorax detection improves with novel enhancement software; the largest improvement is seen in less experienced readers.

Aedes-borne diseases, such as dengue and chikungunya, are public health threats worldwide. Due to climate change and the expansion of Aedes mosquitoes, several countries are reporting the local transmission of Aedes-borne arboviruses. In 2024, Iran faced a significant rise in the number of imported dengue cases and the first local transmission of the disease in the southern provinces of Hormozgan and Sistan and Baluchistan. This review summarizes the latest data on the distribution of invasive Aedes mosquitoes and the epidemiological status of dengue fever and chikungunya in Iran and neighboring countries. A comprehensive search was carried out on papers and reports concerning epidemiological records and studies on dengue fever, chikungunya, Aedes aegypti (Ae. aegypti), and Aedes albopictus (Ae. Albopictus), as well as the recent situation in Iran and neighboring countries since 2000. Meanwhile, the epidemiological trend and milestones of these arboviruses and their vectors in Iran and their last updates in neighboring countries were assessed. In addition to Iran, at least nine neighboring countries including Armenia, Turkey, Iraq, Afghanistan, Pakistan, the United Arab Emirates, Oman, Qatar, and Saudi Arabia have reported the establishment of Ae. aegypti and/or Ae. albopictus mosquitoes. Local dengue virus transmission was reported in Iran, Pakistan, Afghanistan, Oman, the United Arab Emirates, and Saudi Arabia. However, the local circulation of chikungunya virus was only reported in Pakistan. The establishment of Ae. aegypti in southern Iran (Hormozgan, Sistan and Baluchistan, Bushehr) and Ae. albopictus in northern/northwestern provinces (Guilan, Mazandaran, Ardabil, East Azerbaijan, Zanjan, Qazvin) has created distinct arbovirus transmission risks. Local dengue outbreaks in 2024 were exclusively reported in Ae. aegypti-infested areas (Chabahar, Bandar Lengeh), correlating with this vector's known efficiency in urban transmission. While chikungunya remains undocumented in local mosquito populations, serological evidence and recent report of the infected non-Aedes species suggest potential cryptic circulation. With climate models predicting habitat expansion for both vectors, Iran's emerging Aedes-borne diseases' burden could escalate if no action is planned. This underscores the imperative for integrated surveillance targeting mosquito distributions, human case trends, and cross-border pathogen flow to mitigate outbreak risks.

Data encoding is a fundamental step in emerging computing paradigms, particularly in stochastic computing (SC) and hyperdimensional computing (HDC), where it plays a crucial role in determining the overall system performance and hardware cost efficiency. This study presents an advanced encoding strategy that leverages a hardware-friendly class of low-discrepancy (LD) sequences, specifically powers-of-2 bases of Van der Corput (VDC) sequences (VDC-2^n), as sources for random number generation. Our approach significantly enhances the accuracy and efficiency of SC and HDC systems by addressing challenges associated with randomness. By employing LD sequences, we improve correlation properties and reduce hardware complexity. Experimental results demonstrate significant improvements in accuracy and energy savings for SC and HDC systems. Our solution provides a robust framework for integrating SC and HDC in resource-constrained environments, paving the way for efficient and scalable AI implementations.

Hyperdimensional computing (HDC) is a novel computational paradigm that operates on long-dimensional vectors known as hypervectors. The hypervectors are constructed as long bit-streams and form the basic building blocks of HDC systems. In HDC, hypervectors are generated from scalar values without taking their bit significance into consideration. HDC has been shown to be efficient and robust in various data processing applications, including computer vision tasks. To construct HDC models for vision applications, the current state-of-the-art practice utilizes two parameters for data encoding: pixel intensity and pixel position. However, the intensity and position information embedded in high-dimensional vectors are generally not generated dynamically in the HDC models. Consequently, the optimal design of hypervectors with high model accuracy requires powerful computing platforms for training. A more efficient approach to generating hypervectors is to create them dynamically during the training phase, which results in accurate, low-cost, and highly performable vectors. To this aim, we use low-discrepancy sequences to generate intensity hypervectors only, while avoiding position hypervectors. By doing so, the multiplication step in vector encoding is eliminated, resulting in a power-efficient HDC system. For the first time in the literature, our proposed approach employs lightweight vector generators utilizing unary bit-streams for efficient encoding of data instead of using conventional comparator-based generators.

Hyperdimensional computing (HDC) is an emerging computing paradigm that imitates the brain's structure to offer a powerful and efficient processing and learning model. In HDC, the data are encoded with long vectors, called hypervectors, typically with a length of 1K to 10K. The literature provides several encoding techniques to generate orthogonal or correlated hypervectors, depending on the intended application. The existing surveys in the literature often focus on the overall aspects of HDC systems, including system inputs, primary computations, and final outputs. However, this study takes a more specific approach. It zeroes in on the HDC system input and the generation of hypervectors, directly influencing the hypervector encoding process. This survey brings together various methods for hypervector generation from different studies and explores the limitations, challenges, and potential benefits they entail. Through a comprehensive exploration of this survey, readers will acquire a profound understanding of various encoding types in HDC and gain insights into the intricate process of hypervector generation for diverse applications.

As the demand for efficient, low-power computing in embedded and edge devices grows, traditional computing methods are becoming less effective for handling complex tasks. Stochastic computing (SC) offers a promising alternative by approximating complex arithmetic operations, such as addition and multiplication, using simple bitwise operations, like majority or AND, on random bit-streams. While SC operations are inherently fault-tolerant, their accuracy largely depends on the length and quality of the stochastic bit-streams (SBS). These bit-streams are typically generated by CMOS-based stochastic bit-stream generators that consume over 80% of the SC system's power and area. Current SC solutions focus on optimizing the logic gates but often neglect the high cost of moving the bit-streams between memory and processor. This work leverages the physics of emerging ReRAM devices to implement the entire SC flow in place: (1) generating low-cost true random numbers and SBSs, (2) conducting SC operations, and (3) converting SBSs back to binary. Considering the low reliability of ReRAM cells, we demonstrate how SC's robustness to errors copes with ReRAM's variability. Our evaluation shows significant improvements in throughput (1.39x, 2.16x) and energy consumption (1.15x, 2.8x) over state-of-the-art (CMOS- and ReRAM-based) solutions, respectively, with an average image quality drop of 5% across multiple SBS lengths and image processing tasks.

Stochastic Computing (SC) is an unconventional computing paradigm processing data in the form of random bit-streams. The accuracy and energy efficiency of SC systems highly depend on the stochastic number generator (SNG) unit that converts the data from conventional binary to stochastic bit-streams. Recent work has shown significant improvement in the efficiency of SC systems by employing low-discrepancy (LD) sequences such as Sobol and Halton sequences in the SNG unit. Still, the usage of many well-known random sequences for SC remains unexplored. This work studies some new random sequences for potential application in SC. Our design space exploration proposes a promising random number generator for accurate and energy-efficient SC. We propose P2LSG, a low-cost and energy-efficient Low-discrepancy Sequence Generator derived from Powers-of-2 VDC (Van der Corput) sequences. We evaluate the performance of our novel bit-stream generator for two SC image and video processing case studies: image scaling and scene merging. For the scene merging task, we propose a novel SC design for the first time. Our experimental results show higher accuracy and lower hardware cost and energy consumption compared to the state-of-the-art.