Charles Archer
About Charles Archer
Charles Archer CTO
Charles Archer is the Chief Technology Officer with a distinguished background in technology leadership. He has held senior leadership positions at prominent companies including IBM, Intel, Akuna Capital, and Jump Trading. His experience has established him as a notable figure in the fields of high-performance computing (HPC) and trading technology.
Charles Archer Education and Expertise
Charles Archer holds a Master's degree in Chemistry from Columbia University and a Master's degree in Computer Science from the University of Minnesota. His educational background provides a strong foundation in both scientific and computational disciplines, contributing to his expertise in engineering, high-performance computing, and software development.
Charles Archer Technical Leadership at IBM
During his tenure at IBM, Charles Archer served as the Technical Chief Engineering Manager for the IBM Parallel Environment. He was responsible for designing, specifying, and implementing essential components such as job launch, tools, message passing architecture, and scale deployments for various generations of Blue Gene, Power, and x86 systems. His work significantly contributed to the advancement of IBM's high-performance computing capabilities.
Charles Archer Contributions to Intel
At Intel, Charles Archer was instrumental in developing cutting-edge, low instruction-count MPI implementations for high-performance networks. His contributions were vital in enhancing the efficiency and performance of Intel's high-performance computing solutions, further cementing his reputation as an expert in the field.
Charles Archer Work at Akuna Capital and Jump Trading
Charles Archer led teams at Akuna Capital and Jump Trading, focusing on the development of options market-making trading platforms. These platforms specialized in ultra-low latency and high-volume processing at scale. His leadership in this area ensured the creation of efficient and robust trading systems capable of handling significant volumes with minimal delay.