Optical Engineer Level 4

Monarch Quantum•San Diego, CA

43d•$150,000 - $200,000

About The Position

Join our fast-paced and passionate team as a Principal Optical Engineer. As we scale, you will be instrumental in building our foundation from the ground up. This is a dynamic, hands-on role for a self-starter who thrives in a fluid startup environment. You'll have the opportunity to work on cutting edge technologies, work closely with leadership, and develop and implement engineering practices that support our mission and growth. Your key responsibilities are as follows: Work independently and in a team while overcommunicating with the manager, project engineer, and teammates. Execute complex engineering tasks involving planning, preparation, data/information collection, and analysis and decision-making in a process involving peer reviews and documentation of the results. Use tenacity, patience, self-discipline, and passion for excellence to assure accuracy of execution schedule, data quality/integrity, conformance to company best practices, clarity in communication, and documentation Use every opportunity to grow competency through mentorship, curiosity, communication, exposure, and initiative Drive innovation in modeling, design, analysis, and alignment methods to support product roadmap Support project engineering with project scope, schedule, and risk analysis This position requires access to export-controlled information. Employment is contingent upon the applicant being a U.S. person as defined by 8 U.S.C. § 1324b(a)(3).

Requirements

A bachelor’s degree in Optical Engineering, Physics, or a related field
Minimum of 9 years of relevant experience, ideally within a startup or technology company.
Deep understanding of laser beam propagation: how optic movement and rotation impact a beam’s near-field, far-field, beam quality, and fiber coupling efficiency
Fluency applying ray-equivalent methods of laser propagation to guide architecture and debug layout questions
Fluency determining the best way to answer a design problem, including combinations of design software, macros, external code, and manual calculations
Ability to use paraxial raytracing and ABCD matrices to derive analytical expressions for trends, sensitivities, and scaling factors in various optical layouts
Fluency in applying first-order imaging and the overlap integral of Gaussian beams to interrogate the design space of a laser module
Understanding of how component properties impact alignment sensitivity (e.g. collimation lens focal length)
Ability to take a novel optical design question, distill it to an algebraic method, and validate the analysis using a second calculation method (e.g. optical design software).
Ability to turn exotic optical requirements into concrete analysis tasks (e.g. acousto-optic modulator RF tuning range, impact of thermal lensing)
Fluency in applying first-order imaging and the overlap integral of Gaussian beams to derive component fabrication and alignment requirements
Ability to derive quantitative requirements for optic prescriptions (surface roughness, scratch/dig, surface power, surface irregularity, aspheric sag error, material properties)
Understanding of different tolerancing methods for conventionally polished, sub-aperture polished, and precision glass molded components
Ability to engage vendors to understand capabilities and drive clarity to get quotes for components, accounting for supplier yield, risk, and schedule
Understanding of optical metrology methods and how to specify a drawing congruent with a vendor’s measurement facilities
Fluency creating efficient layout optimization workflows in non-sequential design software for nontrivial architectures
Understanding of polarization ray tracing and how to analyze polarization through optic trains with dozens of surfaces
Understanding of polarization components within both Jones and Mueller models
Deep understanding of fiber optics for high power CW laser systems: multi-mode, single mode, polarization maintaining, step index, photonic crystal, endcaps
Understanding of stray light analysis in the context of a laser system
Demonstrated successful execution of engineering tasks including use of design software (Ansys Zemax OpticStudio, Photon Engineering FRED, and/or Lambda Research OSLO preferred) and quantitative analysis/programming tools (Python), instrumentation and measurement, part fabrication or procurement, integration and test, data collection, and documentation
Startup Mindset: You're creative, flexible, and eager to wear multiple hats.
You're passionate about building systems from the ground up and comfortable with ambiguity and change.

Responsibilities

Work independently and in a team while overcommunicating with the manager, project engineer, and teammates.
Execute complex engineering tasks involving planning, preparation, data/information collection, and analysis and decision-making in a process involving peer reviews and documentation of the results.
Use tenacity, patience, self-discipline, and passion for excellence to assure accuracy of execution schedule, data quality/integrity, conformance to company best practices, clarity in communication, and documentation
Use every opportunity to grow competency through mentorship, curiosity, communication, exposure, and initiative
Drive innovation in modeling, design, analysis, and alignment methods to support product roadmap
Support project engineering with project scope, schedule, and risk analysis