About Neuralink:
We are creating devices that enable a bi-directional interface with the brain. These devices allow us to restore movement to the paralyzed, restore sight to the blind, and revolutionize how humans interact with their digital world.
Team Description:
The Brain Interfaces Soc Department delivers chip architecture and silicon implementation of neural recording and stimulation system-on-chip (SoC) for high-bandwidth brain-machine interface applications. We have crafted a team of exceptional engineers whose mission is to push the frontiers of what is possible today and define the future.
Job Description & Responsibilities:
Our Digital IC Design Engineer will be responsible for delivering micro-architecture and register-transfer level (RTL) implementation of digital IPs and systems with a focus in high-throughput low-power digital signal processor (DSP) and general-purpose hardware accelerators towards realizing state-of-the-art brain-computer interfaces. Relevant product development experience in micro-architecture design for low-power processors, on-chip bus and network interfaces, audio/video compression processors, AI/ML accelerators, and communication PHY/MAC will be preferred.
- Micro-architecture design and RTL implementation of:
- Low-power digital signal processors
- Low-power general-purpose hardware accelerators
- Low-power graphics processing units
- Low-power radio MAC/PHY
- Low-power serial link MAC/PHY
- Design and optimization of hardware/software interface with firmware engineers
- Application-specific architecture optimization including:
- Complex system modeling for energy and performance benchmarks
- Workload analysis and modeling
- Energy/performance profiling and analysis
- Leveraging architecture-level design trade-offs with process technology and workload type
- Balancing cost and performance under manufacturing process variation
- Collaboration on silicon bring-up tests with verification engineers
Required Qualifications:
- Evidence of exceptional ability in electrical engineering, computer science, or computer engineering
- 5+ years of experience in digital design
- Expertise in SystemVerilog, C/C++, Python
- Experience working on complex digital systems from architecture, microarchitecture, and RTL, using industry standard tools
- Experience in designing digital signal processing pipelines, from algorithm to RTL
Preferred Qualifications:
- Experience in architecture optimization with process technology customization
- Experience in the verification of complex digital systems, using industry standard tools
- Experience in the physical design of complex digital systems, using industry standard tools
- Experience testing and debugging digital system-on-a-chips
- Functional modeling experience and logic verification with SystemVerilog, SystemC/C++
- Experience automating tool flows
- Experience with embedded design
- Experience in processor instruction set architecture design
- Experience in compiler back-end design and customization
Expected Compensation:
At Neuralink, your base pay is one part of your total compensation package. The anticipated base salary for this position is expected to be within the below range. Your actual base pay will be determined by your job-related skills, experience, and relevant education or training.
Texas Base Salary Range
$101,300—$210,400 USD
What We Offer:
Full-time employees are eligible for the following benefits listed below.
- An opportunity to change the world and work with some of the smartest and most talented experts from different fields
- Growth potential; we rapidly advance team members who have an outsized impact
- Excellent medical, dental, and vision insurance through a PPO plan
- Paid holidays
- Commuter benefits
- Meals provided
- Equity + 401(k) plan *Temporary Employees & Interns excluded
- Parental leave *Temporary Employees & Interns excluded
- Flexible time off *Temporary Employees & Interns excluded
Top Skills
What We Do
Neuralink is a team of exceptionally talented people. We are creating the future of brain-machine interfaces: building devices now that will help people with paralysis and inventing new technologies that will expand our abilities, our community, and our world.
Our goal is to build a system with at least two orders of magnitude more communication channels (electrodes) than current clinically-approved devices. This system needs to be safe, it must have fully wireless communication through the skin, and it has to be ready for patients to take home and use on their own. Our device, called the Link, will be able to record from 1024 electrodes and is designed to meet these criteria.
