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1. Parameter Setting Heuristics Make the Quantum Approximate Optimization Algorithm Suitable for the Early Fault-Tolerant Era

Author

He, Zichang, Shaydulin, Ruslan, Herman, Dylan, Li, Changhao, Raymond, Rudy, Sureshbabu, Shree Hari, and Pistoia, Marco

Subjects
Quantum Physics, Computer Science - Emerging Technologies
Abstract

Quantum Approximate Optimization Algorithm (QAOA) is one of the most promising quantum heuristics for combinatorial optimization. While QAOA has been shown to perform well on small-scale instances and to provide an asymptotic speedup over state-of-the-art classical algorithms for some problems, fault-tolerance is understood to be required to realize this speedup in practice. The low resource requirements of QAOA make it particularly suitable to benchmark on early fault-tolerant quantum computing (EFTQC) hardware. However, the performance of QAOA depends crucially on the choice of the free parameters in the circuit. The task of setting these parameters is complicated in the EFTQC era by the large overheads, which preclude extensive classical optimization. In this paper, we summarize recent advances in parameter setting in QAOA and show that these advancements make EFTQC experiments with QAOA practically viable., Comment: 7 pages, an invited paper at ICCAD 2024 "Exploring Quantum Technologies in Practical Applications" special session

Published
2024

2. Prospects of Privacy Advantage in Quantum Machine Learning

Author

Heredge, Jamie, Kumar, Niraj, Herman, Dylan, Chakrabarti, Shouvanik, Yalovetzky, Romina, Sureshbabu, Shree Hari, Li, Changhao, and Pistoia, Marco

Subjects
Quantum Physics, Computer Science - Machine Learning
Abstract

Ensuring data privacy in machine learning models is critical, particularly in distributed settings where model gradients are typically shared among multiple parties to allow collaborative learning. Motivated by the increasing success of recovering input data from the gradients of classical models, this study addresses a central question: How hard is it to recover the input data from the gradients of quantum machine learning models? Focusing on variational quantum circuits (VQC) as learning models, we uncover the crucial role played by the dynamical Lie algebra (DLA) of the VQC ansatz in determining privacy vulnerabilities. While the DLA has previously been linked to the classical simulatability and trainability of VQC models, this work, for the first time, establishes its connection to the privacy of VQC models. In particular, we show that properties conducive to the trainability of VQCs, such as a polynomial-sized DLA, also facilitate the extraction of detailed snapshots of the input. We term this a weak privacy breach, as the snapshots enable training VQC models for distinct learning tasks without direct access to the original input. Further, we investigate the conditions for a strong privacy breach where the original input data can be recovered from these snapshots by classical or quantum-assisted polynomial time methods. We establish conditions on the encoding map such as classical simulatability, overlap with DLA basis, and its Fourier frequency characteristics that enable such a privacy breach of VQC models. Our findings thus play a crucial role in detailing the prospects of quantum privacy advantage by guiding the requirements for designing quantum machine learning models that balance trainability with robust privacy protection., Comment: 28 pages, 8 figures, 1 table

Published
2024

6. Quantum option pricing via the Karhunen-Lo\`{e}ve expansion

Author

Prakash, Anupam, Sun, Yue, Chakrabarti, Shouvanik, Che, Charlie, Dandapani, Aditi, Herman, Dylan, Kumar, Niraj, Sureshbabu, Shree Hari, Wood, Ben, Kerenidis, Iordanis, and Pistoia, Marco

Subjects
Quantum Physics
Abstract

We consider the problem of pricing discretely monitored Asian options over $T$ monitoring points where the underlying asset is modeled by a geometric Brownian motion. We provide two quantum algorithms with complexity poly-logarithmic in $T$ and polynomial in $1/\epsilon$, where $\epsilon$ is the additive approximation error. Our algorithms are obtained respectively by using an $O(\log T)$-qubit semi-digital quantum encoding of the Brownian motion that allows for exponentiation of the stochastic process and by analyzing classical Monte Carlo algorithms inspired by the semi-digital encodings. The best quantum algorithm obtained using this approach has complexity $\widetilde{O}(1/\epsilon^{3})$ where the $\widetilde{O}$ suppresses factors poly-logarithmic in $T$ and $1/\epsilon$. The methods proposed in this work generalize to pricing options where the underlying asset price is modeled by a smooth function of a sub-Gaussian process and the payoff is dependent on the weighted time-average of the underlying asset price.

Published
2024

7. Expressive variational quantum circuits provide inherent privacy in federated learning

Author

Kumar, Niraj, Heredge, Jamie, Li, Changhao, Eloul, Shaltiel, Sureshbabu, Shree Hari, and Pistoia, Marco

Subjects
Quantum Physics, Computer Science - Cryptography and Security, Computer Science - Machine Learning
Abstract

Federated learning has emerged as a viable distributed solution to train machine learning models without the actual need to share data with the central aggregator. However, standard neural network-based federated learning models have been shown to be susceptible to data leakage from the gradients shared with the server. In this work, we introduce federated learning with variational quantum circuit model built using expressive encoding maps coupled with overparameterized ans\"atze. We show that expressive maps lead to inherent privacy against gradient inversion attacks, while overparameterization ensures model trainability. Our privacy framework centers on the complexity of solving the system of high-degree multivariate Chebyshev polynomials generated by the gradients of quantum circuit. We present compelling arguments highlighting the inherent difficulty in solving these equations, both in exact and approximate scenarios. Additionally, we delve into machine learning-based attack strategies and establish a direct connection between overparameterization in the original federated learning model and underparameterization in the attack model. Furthermore, we provide numerical scaling arguments showcasing that underparameterization of the expressive map in the attack model leads to the loss landscape being swamped with exponentially many spurious local minima points, thus making it extremely hard to realize a successful attack. This provides a strong claim, for the first time, that the nature of quantum machine learning models inherently helps prevent data leakage in federated learning., Comment: 24 pages, 13 figures

Published
2023

8. The Adjoint Is All You Need: Characterizing Barren Plateaus in Quantum Ans\'atze

Author

Fontana, Enrico, Herman, Dylan, Chakrabarti, Shouvanik, Kumar, Niraj, Yalovetzky, Romina, Heredge, Jamie, Sureshbabu, Shree Hari, and Pistoia, Marco

Subjects
Quantum Physics
Abstract

Using tools from the representation theory of compact Lie groups, we formulate a theory of Barren Plateaus (BPs) for parameterized quantum circuits whose observables lie in their dynamical Lie algebra (DLA), a setting that we term Lie algebra Supported Ansatz (LASA). A large variety of commonly used ans\"atze such as the Hamiltonian Variational Ansatz, Quantum Alternating Operator Ansatz, and many equivariant quantum neural networks are LASAs. In particular, our theory provides, for the first time, the ability to compute the variance of the gradient of the cost function of the quantum compound ansatz. We rigorously prove that, for LASA, the variance of the gradient of the cost function, for a 2-design of the dynamical Lie group, scales inversely with the dimension of the DLA, which agrees with existing numerical observations. In addition, to motivate the applicability of our results for 2-designs to practical settings, we show that rapid mixing occurs for LASAs with polynomial DLA. Lastly, we include potential extensions for handling cases when the observable lies outside of the DLA and the implications of our results.

Published
2023
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9. Alzheimer’s Disease and Its Treatment Options

Author

Ballapuram, Aishwarya, Wu, Jenny, Oberdorfer, Jack, Pham, Hieu, Shankar, Sitara, and Sureshbabu, Srutika

Abstract

The goal of this literature review is to analyze various treatment options for Alzheimer’s Disease, a neurodegenerative disorder that affects many Americans. Four drugs being studied in the paper include Donepezil, Memantine, Lecanemab, and Rivastigmine. Donepezil is an acetylcholinesterase inhibitor that is used for patients with mild or moderate AD. Memantine is used to block the overflow of glutamate through NMDA receptors and to treat patients with moderate to severe AD. It can be used in combination therapy with Donepezil and Galantamine. Lecanemab is used to target amyloid-beta plaques and to reduce aggregates. Rivastigmine is a carbamate cholinesterase inhibitor that can be used to inhibit both acetylcholinesterase and butyrylcholinesterase for mild to moderate cases of AD. All four drugs have been shown to slow down the progression of AD by increasing cognitive performance and to improve the quality of life for patients and their caregivers

Published
2023

12. Parameter Setting in Quantum Approximate Optimization of Weighted Problems

Author

Sureshbabu, Shree Hari, Herman, Dylan, Shaydulin, Ruslan, Basso, Joao, Chakrabarti, Shouvanik, Sun, Yue, and Pistoia, Marco

Subjects
Quantum Physics
Abstract

Quantum Approximate Optimization Algorithm (QAOA) is a leading candidate algorithm for solving combinatorial optimization problems on quantum computers. However, in many cases QAOA requires computationally intensive parameter optimization. The challenge of parameter optimization is particularly acute in the case of weighted problems, for which the eigenvalues of the phase operator are non-integer and the QAOA energy landscape is not periodic. In this work, we develop parameter setting heuristics for QAOA applied to a general class of weighted problems. First, we derive optimal parameters for QAOA with depth $p=1$ applied to the weighted MaxCut problem under different assumptions on the weights. In particular, we rigorously prove the conventional wisdom that in the average case the first local optimum near zero gives globally-optimal QAOA parameters. Second, for $p\geq 1$ we prove that the QAOA energy landscape for weighted MaxCut approaches that for the unweighted case under a simple rescaling of parameters. Therefore, we can use parameters previously obtained for unweighted MaxCut for weighted problems. Finally, we prove that for $p=1$ the QAOA objective sharply concentrates around its expectation, which means that our parameter setting rules hold with high probability for a random weighted instance. We numerically validate this approach on general weighted graphs and show that on average the QAOA energy with the proposed fixed parameters is only $1.1$ percentage points away from that with optimized parameters. Third, we propose a general heuristic rescaling scheme inspired by the analytical results for weighted MaxCut and demonstrate its effectiveness using QAOA with the XY Hamming-weight-preserving mixer applied to the portfolio optimization problem. Our heuristic improves the convergence of local optimizers, reducing the number of iterations by 7.4x on average., Comment: Accepted to Quantum Journal

Published
2023
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13. Characterizing barren plateaus in quantum ansätze with the adjoint representation

Author

Enrico Fontana, Dylan Herman, Shouvanik Chakrabarti, Niraj Kumar, Romina Yalovetzky, Jamie Heredge, Shree Hari Sureshbabu, and Marco Pistoia

Subjects
Science
Abstract

Abstract Variational quantum algorithms, a popular heuristic for near-term quantum computers, utilize parameterized quantum circuits which naturally express Lie groups. It has been postulated that many properties of variational quantum algorithms can be understood by studying their corresponding groups, chief among them the presence of vanishing gradients or barren plateaus, but a theoretical derivation has been lacking. Using tools from the representation theory of compact Lie groups, we formulate a theory of barren plateaus for parameterized quantum circuits whose observables lie in their dynamical Lie algebra, covering a large variety of commonly used ansätze such as the Hamiltonian Variational Ansatz, Quantum Alternating Operator Ansatz, and many equivariant quantum neural networks. Our theory provides, for the first time, the ability to compute the exact variance of the gradient of the cost function of the quantum compound ansatz, under mixing conditions that we prove are commonplace.

Published
2024
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14. Adult Philadelphia-Positive Acute Lymphoblastic Leukemia: A Single-Institution Experience in Limited-Resource Setting

Author

Rudresha Haleshappa Antapura, Amale Baburao Vaibhav, Lokanatha Dasappa, Linu Abraham Jacob, Mallekavu Channappa Sureshbabu, Kadabur Nagendrappa Lokesh, Lakkavalli Krishnappa Rajeev, Smitha C. Saldanha, and Tirumala Venkatesh

Subjects
adult, breakpoint cluster region-ABL1, Philadelphia-positive acute lymphoblastic leukemia, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Published
2024
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16. Flavonoids

Author

Abidharini, Jothi Dheivasikamani, primary, Pavithra, Ayyadurai, additional, Boro, Arthi, additional, Sampathkumar, Palanisamy, additional, Sivakumar, Ramalingam, additional, Renuka, Saravanan, additional, Suruthi, Gunna Sureshbabu, additional, and Anand, Arumugam Vijaya, additional

Published
2024
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17. A systems design approach for the co-design of a humanoid robot arm

Author

Sathuluri, Akhil, Sureshbabu, Anand Vazhapilli, and Zimmermann, Markus

Subjects
Computer Science - Robotics
Abstract

Classically, the development of humanoid robots has been sequential and iterative. Such bottom-up design procedures rely heavily on intuition and are often biased by the designer's experience. Exploiting the non-linear coupled design space of robots is non-trivial and requires a systematic procedure for exploration. We adopt the top-down design strategy, the V-model, used in automotive and aerospace industries. Our co-design approach identifies non-intuitive designs from within the design space and obtains the maximum permissible range of the design variables as a solution space, to physically realise the obtained design. We show that by constructing the solution space, one can (1) decompose higher-level requirements onto sub-system-level requirements with tolerance, alleviating the "chicken-or-egg" problem during the design process, (2) decouple the robot's morphology from its controller, enabling greater design flexibility, (3) obtain independent sub-system level requirements, reducing the development time by parallelising the development process., Comment: Presented at the Workshop on Development and Design Pipelines - From first ideas to well-functioning robots, 2022 IEEE-RAS International Conference on Humanoid Robots (Humanoids 2022)

Published
2022

18. Integrating Acupuncture and Yoga for Pain Management in Knee Osteoarthritis

Author

Sureshbabu venkatasamy, Viknesh Ashokan, and Yashwanth Ramesh Babu

Subjects
knee osteoarthritis, multimodal intervention, naturopathic therapies, acupuncture, yoga, resistance exercise, pain, cam, integrative medicine, Public aspects of medicine, RA1-1270
Abstract

Background: Knee osteoarthritis (OA) is a prevalent and debilitating condition. We explore the potential of a multimodal intervention for managing knee OA, combining naturopathic therapies, acupuncture, yoga, and resistance exercise. Case description: A 68-year-old male presented with a one-year Grade II knee OA history. The patient reported moderate pain and reduced joint mobility, impacting daily activities. Clinical Findings: Initial assessment revealed a Western Ontario and McMaster University Osteoarthritis Index (WOMAC) score of 31 and a Visual Analog Scale (VAS) pain score of 5. Intervention: We provided a protocol to the patient that combined traditional naturopathic treatments, mud and mustard compresses, with evidence-based therapies, acupuncture, and resistance exercise. These modalities were chosen to address the multifaceted symptoms of knee OA, focusing on symptomatic relief and functional improvement. Results: The patient improved functional ability and decreased pain perception. WOMAC scores decreased by 26%, reflecting a notable reduction in OA severity. VAS pain scores decreased by 40%, indicating a substantial reduction in perceived pain intensity. The patient reported improved performance in daily activities, suggesting enhanced functional capacity. They also experienced weight loss and lower blood pressure, potentially contributing to overall well-being and influencing pain management and functional capabilities. Conclusions: The potential benefits of a multifaceted approach to managing knee OA were effective. The decrease in pain perception, improvements in functional ability, and even secondary outcomes like weight loss and blood pressure suggest the potential value of exploring such integrative strategies for improved patient outcomes and enhanced well-being in individuals with knee OA.

Published
2024
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23. Rare Manifestation of ATP1A3 Mutation with Clinical Response to Cannabidiol

Author

Hamza, Ashique, Sureshbabu, Sachin, Krishnadas, NC, Narayanan, Poornima, Pillai, Deep P, and Samuel, Nikhil

Subjects
Gene mutations -- Health aspects, Epilepsy -- Genetic aspects -- Care and treatment, Health
Abstract

Author(s): Ashique Hamza [1]; Sachin Sureshbabu (corresponding author) [1]; NC Krishnadas [1]; Poornima Narayanan [1]; Deep P Pillai [1]; Nikhil Samuel [2] Dear Editor, ATP1A3 mutations span a wide range [...]

Published
2024
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24. Fabrication of folic acid-conjugated pyrimidine-2(5H)-thione-encapsulated curdlan gum-PEGamine nanoparticles for folate receptor targeting breast cancer cells

Author

Kunjiappan, Selvaraj, Panneerselvam, Theivendren, Pavadai, Parasuraman, Balakrishnan, Vanavil, Pandian, Sureshbabu Ram Kumar, Palanisamy, Ponnusamy, Sankaranarayanan, Murugesan, Kabilan, Shanmugampillai Jeyarajaguru, Sundaram, Ganeshraja Ayyakannu, Tseng, Wei-Lung, and Kumar, Alagarsamy Santhana Krishna

Published
2024
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25. Finite-Size Scaling on a Digital Quantum Simulator using Quantum Restricted Boltzmann Machine

Author

Khalid, Bilal, Sureshbabu, Shree Hari, Banerjee, Arnab, and Kais, Sabre

Subjects
Quantum Physics
Abstract

The critical point and the critical exponents for a phase transition can be determined using the Finite-Size Scaling (FSS) analysis. This method assumes that the phase transition occurs only in the infinite size limit. However, there has been a lot of interest recently in quantum phase transitions occuring in finite size systems such as a single two-level system interacting with a single bosonic mode e.g. in the Quantum Rabi Model (QRM). Since, these phase transitions occur at a finite system size, the traditional FSS method is rendered inapplicable for these cases. For cases like this, we propose an alternative FSS method in which the truncation of the system is done in the Hilbert space instead of the physical space. This approach has previously been used to calculate the critical parameters for stability and symmetry breaking of electronic structure configurations of atomic and molecular systems. We calculate the critical point for the quantum phase transition of the QRM using this approach. We also provide a protocol to implement this method on a digital quantum simulator using the Quantum Restricted Boltzmann Machine algorithm. Our work opens up a new direction in the study of quantum phase transitions on quantum devices.

Published
2022

28. Diversity and Phenology of Soybean Seed Fungal Endophyte Communities in the Upper Midwest United States

Author

Jean Carlson Batzer, Amin Shirazi, Maia Lawson, Nabin K. Dangal, Bijula M. Sureshbabu, Febina M. Mathew, Damon L. Smith, and Daren S. Mueller

Subjects
Alternaria, Diaporthe, Fusarium, Glycine max, logistic regression, microbial communities, Plant culture, SB1-1110, Botany, QK1-989
Abstract

Infection over time by endophytic fungi in soybean seed and pods was documented in Iowa and Wisconsin in 2018. Three reproductive stages were sampled from six cultivars, with maturity groups (MG) ranging from 1.1 to 4.7, and included 216 blemish-free pods and 1,836 healthy seeds that were heavily disinfested to remove epiphytes. Thirty-five species and 11 genera were identified from 1,799 isolates using morphological and molecular evidence. Alternaria, Diaporthe, and Fusarium were dominant. The timing of endophyte infection was documented relative to MG. The lowest number of fungi were recovered from seed at R6, and infection sharply increased at R7. The abundance of Diaporthe and Fusarium isolates differed across MG and reproductive stage; shorter MGs had more Diaporthe isolates at earlier reproductive stages than longer MGs. Fusarium counts differed across MG but did not show consistent trends with seed maturity. Alternaria counts declined as seed matured but were not affected by MG. We used nonmetric multidimensional scaling to elucidate the phenology of seed infection within the endophyte community. This method helps represent the data in a lower dimension by measuring the similarity or dissimilarity between data points, making it a useful tool for grouping similar endophyte communities. The nonmetric multidimensional scaling ordination analysis of fungal taxa within endophyte communities revealed that the dominant genera in filled green pods were highly similar. However, this similarity was not observed among different stages of seed development, indicating that each taxon had distinct modes of infecting the seeds. [Figure: see text] Copyright © 2023 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Published
2023
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30. Quantum Machine Learning for Chemistry and Physics

Author

Sajjan, Manas, Li, Junxu, Selvarajan, Raja, Sureshbabu, Shree Hari, Kale, Sumit Suresh, Gupta, Rishabh, Singh, Vinit, and Kais, Sabre

Subjects
Physics - Chemical Physics, Condensed Matter - Materials Science, Quantum Physics
Abstract

Machine learning (ML) has emerged into formidable force for identifying hidden but pertinent patterns within a given data set with the objective of subsequent generation of automated predictive behavior. In the recent years, it is safe to conclude that ML and its close cousin deep learning (DL) have ushered unprecedented developments in all areas of physical sciences especially chemistry. Not only the classical variants of ML , even those trainable on near-term quantum hardwares have been developed with promising outcomes. Such algorithms have revolutionzed material design and performance of photo-voltaics, electronic structure calculations of ground and excited states of correlated matter, computation of force-fields and potential energy surfaces informing chemical reaction dynamics, reactivity inspired rational strategies of drug designing and even classification of phases of matter with accurate identification of emergent criticality. In this review we shall explicate a subset of such topics and delineate the contributions made by both classical and quantum computing enhanced machine learning algorithms over the past few years. We shall not only present a brief overview of the well-known techniques but also highlight their learning strategies using statistical physical insight. The objective of the review is to not only to foster exposition to the aforesaid techniques but also to empower and promote cross-pollination among future-research in all areas of chemistry which can benefit from ML and in turn can potentially accelerate the growth of such algorithms.

Published
2021
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33. National cross-sectional cluster survey of tuberculosis prevalence in Timor-Leste: a study protocol

Author

Joana Dias, Joshua Reginald Francis, Jennifer Yan, Christopher Lowbridge, Nelson Martins, Salvador Amaral, Tessa Oakley, Nevio Sarmento, Endang da Silva, Constantino Lopes, Josefina Clarinha Joao, Rofina Isabel Gusmão dos Santos, Sureshbabu Ramalingam, and Lourenco da Costa Ico

Subjects
Medicine
Abstract

Introduction Timor-Leste has one of the world’s highest estimated tuberculosis (TB) incidences, yet the data which informs this estimate is limited and the true burden of TB disease is not known. TB prevalence surveys offer the best means of determining robust estimates of disease burden. This study aims to provide an estimate of the prevalence of bacteriologically confirmed pulmonary TB in Timor-Leste and provide additional insights into diagnostic coverage and health-seeking behaviour of persons with symptoms suggestive of TB.Methods and analysis A national population-based cross-sectional cluster survey will be conducted in which participants aged 15 years and older will be screened for pulmonary TB using an algorithm consisting of symptom screening and digital X-ray of the chest with computer-aided detection software for X-ray interpretation. Xpert Ultra and liquid culture methods will be used to confirm survey TB cases. Additional data will be collected from persons reporting symptoms suggestive of TB to assess health-seeking behaviour and access to TB diagnosis and care. The survey aims to screen a target sample population of 20 068 people, living within 50 clusters, representing every municipality of Timor-Leste. Bacteriologically confirmed pulmonary TB prevalence will be estimated using WHO-recommended methods.Ethics and dissemination Research ethics approval has been granted by the human research ethics committee of the Northern Territory, Australia, and the Instituto Nacional da Saúde, Timor-Leste. The results will be published in a peer-reviewed scientific journal and disseminated with relevant stakeholders.Trial registration number ACTRN12623000718640.

Published
2024
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39. Quantum Machine-Learning for Eigenstate Filtration in Two-Dimensional Materials

Author

Sajjan, Manas, Sureshbabu, Shree Hari, and Kais, Sabre

Subjects
Physics - Chemical Physics
Abstract

Quantum machine learning algorithms have emerged to be a promising alternative to their classical counterparts as they leverage the power of quantum computers. Such algorithms have been developed to solve problems like electronic structure calculations of molecular systems and spin models in magnetic systems. However the discussion in all these recipes focus specifically on targeting the ground state. Herein we demonstrate a quantum algorithm that can filter any energy eigenstate of the system based on either symmetry properties or on a predefined choice of the user. The work horse of our technique is a shallow neural network encoding the desired state of the system with the amplitude computed by sampling the Gibbs- Boltzmann distribution using a quantum circuit and the phase information obtained classically from the non-linear activation of a separate set of neurons. We show that the resource requirements of our algorithm is strictly quadratic. To demonstrate its efficacy, we use state-filtration in monolayer transition metal-dichalcogenides which are hitherto unexplored in any flavor of quantum simulations. We implement our algorithm not only on quantum simulators but also on actual IBM-Q quantum devices and show good agreement with the results procured from conventional electronic structure calculations. We thus expect our protocol to provide a new alternative in exploring band-structures of exquisite materials to usual electronic structure methods or machine learning techniques which are implementable solely on a classical computer

Published
2021
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40. A Plenum-Based Calibration Device for Tactile Sensor Arrays

Author

Kangro, Joan, Sureshbabu, Anand Vazhapilli, Traversaro, Silvio, Pucci, Daniele, and Nori, Francesco

Subjects
Computer Science - Robotics
Abstract

In modern robotic applications, tactile sensor arrays (i.e., artificial skins) are an emergent solution to determine the locations of contacts between a robot and an external agent. Localizing the point of contact is useful but determining the force applied on the skin provides many additional possibilities. This additional feature usually requires time-consuming calibration procedures to relate the sensor readings to the applied forces. This letter presents a novel device that enables the calibration of tactile sensor arrays in a fast and simple way. The key idea is to design a plenum chamber where the skin is inserted, and then the calibration of the tactile sensors is achieved by relating the air pressure and the sensor readings. This general concept is tested experimentally to calibrate the skin of the iCub robot. The validation of the calibration device is achieved by placing the masses of known weight on the artificial skin and comparing the applied force against the one estimated by the sensors., Comment: 8 pages, 18 figures

Published
2021
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41. Implementation of Quantum Machine Learning for Electronic Structure Calculations of Periodic Systems on Quantum Computing Devices

Author

Sureshbabu, Shree Hari, Sajjan, Manas, Oh, Sangchul, and Kais, Sabre

Subjects
Physics - Computational Physics, Condensed Matter - Materials Science, Quantum Physics
Abstract

Quantum machine learning algorithms, the extensions of machine learning to quantum regimes, are believed to be more powerful as they leverage the power of quantum properties. Quantum machine learning methods have been employed to solve quantum many-body systems and have demonstrated accurate electronic structure calculations of lattice models, molecular systems, and recently periodic systems. A hybrid approach using restricted Boltzmann machines and a quantum algorithm to obtain the probability distribution that can be optimized classically is a promising method due to its efficiency and ease of implementation. Here we implement the benchmark test of the hybrid quantum machine learning on the IBM-Q quantum computer to calculate the electronic structure of typical 2-dimensional crystal structures: hexagonal-Boron Nitride and graphene. The band structures of these systems calculated using the hybrid quantum machine learning are in good agreement with those obtained by the conventional electronic structure calculation. This benchmark result implies that the hybrid quantum machine learning, empowered by quantum computers, could provide a new way of calculating the electronic structures of quantum many-body systems.

Published
2021

44. Data Homogeneity Dependent Topic Modeling for Information Retrieval

Author

Kashi, Keerthana Sureshbabu, Antenor, Abigail A., Ramolete, Gabriel Isaac L., Heinrich, Adrienne, Akan, Ozgur, Editorial Board Member, Bellavista, Paolo, Editorial Board Member, Cao, Jiannong, Editorial Board Member, Coulson, Geoffrey, Editorial Board Member, Dressler, Falko, Editorial Board Member, Ferrari, Domenico, Editorial Board Member, Gerla, Mario, Editorial Board Member, Kobayashi, Hisashi, Editorial Board Member, Palazzo, Sergio, Editorial Board Member, Sahni, Sartaj, Editorial Board Member, Shen, Xuemin, Editorial Board Member, Stan, Mircea, Editorial Board Member, Jia, Xiaohua, Editorial Board Member, Zomaya, Albert Y., Editorial Board Member, Nandan Mohanty, Sachi, editor, Garcia Diaz, Vicente, editor, and Satish Kumar, G. A. E., editor

Published
2023
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49. Molecular dissection and testing of PRSS37 function through LC–MS/MS and the generation of a PRSS37 humanized mouse model

Author

Courtney Sutton, Kaori Nozawa, Katarzyna Kent, Alexander Saltzman, Mei Leng, Sureshbabu Nagarajan, Anna Malovannaya, Masahito Ikawa, Thomas X. Garcia, and Martin M. Matzuk

Subjects
Medicine, Science
Abstract

Abstract The quest for a non-hormonal male contraceptive pill for men still exists. Serine protease 37 (PRSS37) is a sperm-specific protein that when ablated in mice renders them sterile. In this study we sought to examine the molecular sequelae of PRSS37 loss to better understand its molecular function, and to determine whether human PRSS37 could rescue the sterility phenotype of knockout (KO) mice, allowing for a more appropriate model for drug molecule testing. To this end, we used CRISPR-EZ to create mice lacking the entire coding region of Prss37, used pronuclear injection to create transgenic mice expressing human PRSS37, intercrossed these lines to generate humanized mice, and performed LC–MS/MS of KO and control tissues to identify proteomic perturbances that could attribute a molecular function to PRSS37. We found that our newly generated Prss37 KO mouse line is sterile, our human transgene rescues the sterility phenotype of KO mice, and our proteomics data not only yields novel insight into the proteome as it evolves along the male reproductive tract, but also demonstrates the proteins significantly influenced by PRSS37 loss. In summary, we report vast biological insight including insight into PRSS37 function and the generation of a novel tool for contraceptive evaluation.

Published
2023
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