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6G Wireless Jobs (NOW HIRING)

As a member of our 6G Innovation Lab at Ofinno, you will be at the forefront of pioneering advancements in wireless communication technologies. This role involves creating state-of-the-art solutions ...

As a member of our 6G Innovation Lab at Ofinno, you will be at the forefront of pioneering advancements in wireless communication technologies. This role involves creating state-of-the-art solutions ...

Possess a profound understanding of RF propagation, antenna theory, and cutting-edge wireless technologies (4G, 5G, 6G, Wi-Fi-7). * Experience with WiFi-7. - This is the must required on this role.

Sr Wireless Systems Engineer

Bridgewater, NJ · On-site

$122K - $183K/yr

Research, design, and develop advanced wireless communication systems for 6G * Design and optimize PHY/MAC layer algorithms, system architectures, and protocols * Perform system-level modeling ...

The engineer will work on next-generation wireless research involving 5G/6G telemetry architectures, AI-driven network experimentation, spectrum analytics, and integrated sensing and communications ...

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6G Wireless information

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How much do 6g wireless jobs pay per hour?

As of Jul 6, 2026, the average hourly pay for 6g wireless in the United States is $27.74, according to ZipRecruiter salary data. Most workers in this role earn between $25.00 and $30.77 per hour, depending on experience, location, and employer.

What are the key skills and qualifications needed to thrive as a 6G Wireless Engineer, and why are they important?

To thrive as a 6G Wireless Engineer, you need advanced knowledge of wireless communications, signal processing, and network architecture, typically supported by a degree in electrical engineering or a related field. Familiarity with simulation tools (such as MATLAB or NS-3), radio frequency (RF) design software, and emerging technologies like AI/ML integration in networks is crucial. Strong problem-solving abilities, innovation, and effective teamwork distinguish top performers in this evolving area. These skills enable engineers to develop and optimize cutting-edge wireless systems essential for next-generation connectivity.

What is the difference between 6G Wireless vs 5G Wireless Engineer?

Aspect6G Wireless5G Wireless Engineer
Required CredentialsBachelor's or higher in Electrical Engineering, Telecommunications, or related fields; certifications in wireless technologyBachelor's or higher in Electrical Engineering, Telecommunications, or related fields; certifications in wireless technology
Work EnvironmentResearch labs, tech companies, telecom providers focusing on future wireless standardsTelecom companies, network providers, infrastructure firms working on 5G deployment
Industry UsageEmerging research, development, and standardization for 6GDeployment, optimization, and maintenance of 5G networks

While 5G Wireless Engineers focus on current 5G network deployment and optimization, 6G Wireless professionals work on future wireless standards, research, and development. Both roles require similar educational backgrounds and certifications, but 6G is more research-oriented, whereas 5G is actively deployed in the industry.

What are 6G wireless technologies?

6G wireless technologies refer to the next generation of mobile networks that are expected to succeed 5G, offering unprecedented speeds, ultra-low latency, and highly reliable connectivity. 6G is still in the research and development phase, with commercial deployment anticipated around 2030. It aims to support advanced applications such as holographic communications, ubiquitous AI, and enhanced Internet of Things (IoT) integration. The technology will leverage new spectrum bands, including terahertz frequencies, and incorporate cutting-edge advancements in network architecture, security, and energy efficiency.

What are some common challenges faced by professionals working on 6G wireless technology development?

Professionals in 6G wireless technology often encounter challenges related to developing and testing innovative solutions that meet extremely high data rates, ultra-low latency, and massive connectivity demands. Working in this field frequently involves interdisciplinary collaboration with experts in AI, photonics, and cybersecurity, and requires staying up-to-date with rapid advancements. Additionally, the role may involve navigating evolving global standards and regulatory requirements, which can add complexity to research and development projects. These challenges make teamwork, adaptability, and continuous learning essential for success.
More about 6G Wireless jobs
What cities are hiring for 6G Wireless jobs? Cities with the most 6G Wireless job openings:
What states have the most 6G Wireless jobs? States with the most job openings for 6G Wireless jobs include:
Infographic showing various 6G Wireless job openings in the United States as of June 2026, with employment types broken down into 93% Full Time, and 7% Contract. Highlights an 93% In-person, and 7% Remote job distribution, with an average salary of $57,707 per year, or $27.7 per hour.
Industrial Wireless Sensing Systems (Smart Factory, 5G/6G)

Industrial Wireless Sensing Systems (Smart Factory, 5G/6G)

Optimal Inc.

Embry Hills, GA

$42 - $57.75/hr

Contractor

Posted 25 days ago


Job description

Senior Researcher / Senior Engineer - Next-Generation Wireless Precision Sensors

Role Summary
We are seeking a Senior Researcher / Senior Engineer to lead development of next-generation wireless sensing solutions for Future Factory manufacturing systems. This role will focus on high-precision, machine-attachable sensors that can operate in industrial environments and communicate over emerging 5G and 6G networks. The successful candidate will define sensing architectures for manufacturing equipment, prototype and validate high-resolution wireless sensors, and enable real-time data capture for AI-driven process monitoring, quality prediction, and closed-loop optimization.
The ideal candidate combines deep expertise in precision sensing hardware with strong understanding of manufacturing environments, sensor integration constraints, signal quality, and industrial deployment.

What You'll Do
Lead development of wireless sensing concepts for manufacturing equipment and test systems, with emphasis on high precision, robustness, and ease of attachment to existing machines
Define sensing strategies for displacement measurement in the 1-5 micron range, force sensing at Newton-level resolution, acoustic sensing for engine and equipment monitoring, and related high-fidelity industrial measurements
Evaluate and develop sensor technologies such as MEMS-based sensors, piezoelectric sensors, optical or laser displacement sensors, strain-based force sensors, acoustic and ultrasonic sensors, vibration sensors, temperature sensors, and hybrid multi-modal sensing packages
Architect compact, low-power, ruggedized sensor nodes suitable for harsh manufacturing environments including vibration, heat, EMI, oil, dust, and cycle-to-cycle variation
Design and validate sensor packaging, mounting strategies, calibration methods, drift compensation methods, and signal-conditioning approaches for factory deployment
Partner with controls, manufacturing, automation, and AI teams to ensure the sensor outputs are suitable for downstream real-time analytics and digital twin applications
Conduct laboratory and plant-floor experiments to benchmark resolution, repeatability, latency, reliability, battery life, and wireless performance
Develop technical roadmaps for next-generation industrial sensing aligned to 5G/6G connectivity and Future Factory requirements
Support supplier engagement, prototype builds, test plans, technical reviews, and technology down-selection

Required Qualifications
Master's degree or PhD in Electrical Engineering, Mechanical Engineering, Materials Engineering, Applied Physics, Mechatronics, Robotics, or a related field
5+ years of industrial or applied research experience in precision sensors, instrumentation, industrial measurement systems, or smart connected devices

Demonstrated expertise in one or more of the following:

  • Precision displacement sensing
  • Force or strain measurement
  • Acoustic or vibration sensing
  • Industrial instrumentation
  • MEMS sensor systems
  • Wireless embedded sensing


Strong understanding of sensor physics, signal conditioning, noise reduction, calibration, uncertainty analysis, and measurement-system design
Experience developing hardware for industrial or automotive environments
Hands-on experience with data acquisition systems, embedded electronics, sensor interfaces, and experimental validation
Ability to translate manufacturing problems into measurable sensing requirements and deployable hardware solutions
Strong written and verbal communication skills with the ability to work across research, engineering, manufacturing, and supplier teams

Preferred Qualifications
PhD with specialization in advanced sensors, wireless sensing, or industrial instrumentation
Experience with 5G, private wireless networks, ultra-reliable low-latency communications, or edge-connected sensor platforms
Experience with battery-powered or energy-efficient wireless sensor nodes
Familiarity with OPC UA, MQTT, industrial Ethernet, TSN, or edge-to-cloud telemetry frameworks
Experience with sensor fusion, anomaly detection, or AI/ML workflows for industrial process monitoring
Experience in automotive manufacturing, engine testing, welding, casting, assembly, or end-of-line validation
Experience with rugged product design, EMI/EMC considerations, and design-for-manufacturability

Key Skills and Competencies
Precision sensing and instrumentation
Wireless sensor architecture
Embedded hardware development
Signal processing and calibration
Experimental design and validation
Industrial deployment and machine integration
Cross-functional technical leadership
Supplier and prototype management


Success Profile
A strong candidate for this role will be able to take a manufacturing measurement challenge, identify the right sensing mechanism, design a wireless industrial sensor architecture, validate precision and robustness, and create a path toward scalable deployment in a connected factory environment.