Assoc. Prof. Dr. Husheng Wu | Computer Science | Research Excellance Award

Associate professor | Engineering University of PAP | China

Assoc. Prof. Dr. Husheng Wu is an associate-level researcher known for his influential work in swarm intelligence, unmanned systems, and intelligent defense technologies. His background includes advanced studies in engineering disciplines that strengthened his expertise in autonomous decision-making, cooperative control, and intelligent equipment systems. Over the course of his scholarly career, he has produced 74 documents, which have collectively garnered 1,348 citations across 1,091 citing documents, highlighting the measurable impact of his contributions. His research spans multi-agent collaboration, combat simulation, algorithmic intelligence, intelligent task allocation, and adaptive mission planning, with applications across air, ground, and maritime autonomous platforms. In addition to his research, he has contributed to teaching and the development of next-generation defense technologies, earning recognition for advancements in intelligent equipment systems and modern defense engineering.

Profile : Scopus | ORCID

Featured Publications

wu, h., et al. (2023). cooperative control strategies for uav swarm missions. systems engineering journal.

wu, h., & zhang, l. (2022). intelligent combat decision models for unmanned systems. defense technology.

wu, h., et al. (2021). multi-agent optimization algorithms for battlefield applications. journal of military systems.

wu, h. (2020). swarm intelligence for complex combat scenarios. engineering applications in defense.

wu, h., & li, k. (2019). adaptive mission planning for autonomous platforms. international journal of intelligent systems.

Mr Ernesto Diaz | Computer Science | Best Researcher Award

Assistant Specialist at University of California, San Francisco – Radiology & Biomedical Imaging, United States

Ernesto Diaz is a highly skilled Data Scientist at the University of California, San Francisco (UCSF), specializing in Hyperpolarized Carbon-13 Metabolic Imaging within the Department of Radiology and Biomedical Imaging. He earned his Bachelor of Science in Computer Science from San Francisco State University in 2022, consistently achieving Dean’s List honors.

Profile:

Google Scholar

🎓 Education:

San Francisco State University, San Francisco, CA

Bachelor of Science in Computer Science, 2022
Dean’s List: 2020-2022

💻 Technical Skills:

Languages & Environments: Python, R-Code, C++, MATLAB, HTML, CSS, Shell Scripting, CUDA, UNIX
Packages: Pandas, Matplotlib, NumPy, PyDicom, TensorFlow, PyTorch, Tkinter, Conda, CMake

🔬 Research Experience:

Data Scientist
University of California San Francisco, Department of Radiology and Biomedical Imaging
June 2022 – Present

Developed data processing methods for Hyperpolarized Carbon-13 Metabolic Imaging.
Lead developer of a Python application for HP 13C DICOM Images metadata integration.
Co-developed a deep learning image segmentation tool achieving 80% accuracy in prostate cancer segmentation.
Contributed to UCSF’s open-source MR Spectroscopy tool (SIVIC).

Undergraduate Researcher
UCSF, Department of Radiation Oncology
August 2021 – June 2022

Automated 3D spine metastases radiation planning.
Designed a Python/Tkinter GUI for treatment planning, boosting efficiency by 50%.

NIH Funded SF BUILD Scholar
San Francisco State University
June 2021 – June 2022

Selected for leadership potential and dedication to underserved communities.
Focused on diversity in NIH-funded research.

🏆 Awards & Scholarships:

NIH Diversity Supplement Award: 2022-2024
NIH-SF BUILD Scholar: 2021-2022
Dean’s List: San Francisco State University, 2020-2022

📅 Committees & Leadership:

UCSF PROPEL Scholar: Promoting equity in scientific research (2022-2024)
Metro Near-Peer Mentoring Program: Mentored first-year college students (2020-2022)
Google Developer Student Club: Engaged in peer-to-peer learning and community solutions (2019)

🎯 Certifications:

CITI Training Certificate: Social/Behavioral Research, 2022
Near-Peer Mentor Training: Metro Student First, 2020

Publication Top Notes:

The genomic landscape of hypodiploid acute lymphoblastic leukemia
L. Holmfeldt, L. Wei, E. Diaz-Flores, M. Walsh, J. Zhang, L. Ding, …
Nature Genetics, 45(3), 242-252, 2013. (Citations: 841)
Single-cell profiling identifies aberrant STAT5 activation in myeloid malignancies with specific clinical and biologic correlates
N. Kotecha, N.J. Flores, J.M. Irish, E.F. Simonds, D.S. Sakai, S. Archambeault, …
Cancer Cell, 14(4), 335-343, 2008. (Citations: 290)
Ex vivo drug response profiling detects recurrent sensitivity patterns in drug-resistant acute lymphoblastic leukemia
V. Frismantas, M.P. Dobay, A. Rinaldi, J. Tchinda, S.H. Dunn, J. Kunz, …
Blood, The Journal of the American Society of Hematology, 129(11), e26-e37, 2017. (Citations: 240)
p53 loss promotes acute myeloid leukemia by enabling aberrant self-renewal
Z. Zhao, J. Zuber, E. Diaz-Flores, L. Lintault, S.C. Kogan, K. Shannon, …
Genes & Development, 24(13), 1389-1402, 2010. (Citations: 211)
Response and resistance to MEK inhibition in leukaemias initiated by hyperactive Ras
J.O. Lauchle, D. Kim, D.T. Le, K. Akagi, M. Crone, K. Krisman, K. Warner, …
Nature, 461(7262), 411-414, 2009. (Citations: 156)
K-RasG12D expression induces hyperproliferation and aberrant signaling in primary hematopoietic stem/progenitor cells
M.E.M. Van Meter, E. Díaz-Flores, J.A. Archard, E. Passegué, J.M. Irish, …
Blood, 109(9), 3945-3952, 2007. (Citations: 138)
Phase II study of the oral MEK inhibitor selumetinib in advanced acute myelogenous leukemia: a University of Chicago phase II consortium trial
N. Jain, E. Curran, N.M. Iyengar, E. Diaz-Flores, R. Kunnavakkam, …
Clinical Cancer Research, 20(2), 490-498, 2014. (Citations: 133)
Bcl-2 is a therapeutic target for hypodiploid B-lineage acute lymphoblastic leukemia
E. Diaz-Flores, E.Q. Comeaux, K.L. Kim, E. Melnik, K. Beckman, K.L. Davis, …
Cancer Research, 79(9), 2339-2351, 2019. (Citations: 80)
Diacylglycerol kinase inhibition prevents IL-2-induced G1 to S transition through a phosphatidylinositol-3 kinase-independent mechanism
I. Flores, D.R. Jones, A. Ciprés, E. Díaz-Flores, M.A. Sanjuan, I. Mérida
The Journal of Immunology, 163(2), 708-714, 1999. (Citations: 71)
Regulation of diacylglycerol kinase α by phosphoinositide 3-kinase lipid products
A. Ciprés, S. Carrasco, E. Merino, E. Díaz, U.M. Krishna, J.R. Falck, …
Journal of Biological Chemistry, 278(37), 35629-35635, 2003. (Citations: 69)
Targeting oncogenic ras
E. Diaz-Flores, K. Shannon
Genes & Development, 21(16), 1989-1992, 2007. (Citations: 65)
Cooperative loss of RAS feedback regulation drives myeloid leukemogenesis
Z. Zhao, C.C. Chen, C.D. Rillahan, R. Shen, T. Kitzing, M.E. McNerney, …
Nature Genetics, 47(5), 539-543, 2015. (Citations: 48)
Abnormal hematopoiesis in Gab2 mutant mice
Y. Zhang, E. Diaz-Flores, G. Li, Z. Wang, Z. Kang, E. Haviernikova, S. Rowe, …
Blood, 110(1), 116-124, 2007. (Citations: 48)
β2-chimaerin provides a diacylglycerol-dependent mechanism for regulation of adhesion and chemotaxis of T cells
M. Siliceo, D. García-Bernal, S. Carrasco, E. Díaz-Flores, F.C. Leskow, …
Journal of Cell Science, 119(1), 141-152, 2006. (Citations: 48)
Membrane translocation of protein kinase Cθ during T lymphocyte activation requires phospholipase C-γ-generated diacylglycerol
E. Díaz-Flores, M. Siliceo, C. Martínez-A, I. Mérida
Journal of Biological Chemistry, 278(31), 29208-29215, 2003. (Citations: 48)
Rapid screening of COVID‐19 patients using white blood cell scattergrams, a study on 381 patients
J. Osman, J. Lambert, M. Templé, F. Devaux, R. Favre, C. Flaujac, D. Bridoux, …
British Journal of Haematology, 190(5), 718-722, 2020. (Citations: 34)
NRAS G12V oncogene facilitates self-renewal in a murine model of acute myelogenous leukemia
Z. Sachs, R.S. LaRue, H.T. Nguyen, K. Sachs, K.E. Noble, N.A. Mohd Hassan, …
Blood, 124(22), 3274-3283, 2014. (Citations: 30)
PLC-γ and PI3K link cytokines to ERK activation in hematopoietic cells with normal and oncogenic Kras
E. Diaz-Flores, H. Goldschmidt, P. Depeille, V. Ng, J. Akutagawa, K. Krisman, …
Science Signaling, 6(304), ra105-ra105, 2013. (Citations: 21)
Evolution of artificial intelligence-powered technologies in biomedical research and healthcare
E. Diaz-Flores, T. Meyer, A. Giorkallos
Smart Biolabs of the Future, 23-60, 2022. (Citations: 18)
Stat5 is critical for the development and maintenance of myeloproliferative neoplasm initiated by Nf1 deficiency
Z. Sachs, R.A. Been, K.J. DeCoursin, H.T. Nguyen, N.A.M. Hassan, …
Haematologica, 101(10), 1190, 2016. (Citations: 18)