Telecommunications Hub
Q2 2024

How Optical Wireless Communications for Enterprises Can Prevent Cyberattacks

While some optimistically predicted that the decades of the 20s would see history repeat itself, it’s still too soon to tell whether businesses and economies will roar back from the brink of not only a global pandemic but also monumental cybersecurity breaches. Particularly as employees and communication capabilities become increasingly untethered from a fixed location, businesses across the globe are seeking solutions to bolster resiliency, shore up security and increase speed and bandwidth with the deployment of private 4G and 5G networks.

Unlike a public network hosted by a third party, a private cellular network is hosted on-premises. It doesn’t share resources with a third party and only permits access to those devices and users authorized by the organization. Allowing enterprises to determine scale plus the utilized technology and rollout pace, these private networks, with increasing adoption rates, have been deployed by a wide range of organizations to address specific challenges and explore new opportunities.

As 5G becomes more ubiquitous, so too will vulnerabilities. Germany-based Rohde & Schwarz, for example, installed a private 5G network at its plant in Teisnach, Germany, to test new industrial applications and uncover how it could optimize 5G for smart factories. Likewise, the Belgian Port of Zeebrugge deployed a private 5G network to track, analyze and manage connected devices, such as autonomous vehicles, augmented reality and drones, across multiple port-based applications in real-time.

When configuring a private 5G network, spectrum typical comes from three principal ranges:

  • Low-frequency bands under 1 GHz
  • Mid-frequency bands in the core 3.3 GHz to 3.8 GHz range
  • High-frequency mmWave bands in the 26 GHz, 28 GHz and 40 GHz range

Enterprises have three options: licensed spectrum owned by one of the numerous organizations that have purchased Citizens Broadband Radio Service (CBRS), priority access licenses (PALs) in a Federal Communications Commission (FCC) auction or unlicensed band spectrum such as the general authorized access (GAA) tier of the CBRS band. 

While each spectrum brings specific advantages, they also come with inherent risks, given that they are easily hackable radio-frequency (RF) signals. As 5G becomes more ubiquitous, so too will vulnerabilities. This is primarily due to 5G’s heavy reliance on RF, as well as application programming interfaces (APIs) and other supporting service functions.

These APIs expose enterprises to API-enabled hacks like the one used to target SolarWinds. With the cleanup from this cyberattack alone potentially costing more than $100 billion in the months ahead, the stakes are extremely high for both economic stability and national security. In addition to thousands of Fortune 500 companies, the SolarWinds hack affected U.S. Departments of Commerce, Treasury, Homeland Security and Justice.

Inarguably, current security methods are falling short. Meanwhile, threats to our nation extend to vital areas such as utilities, food, water, oil and gas. Colonial Pipeline may be just the first of what is to come, which is why National Guard simulations are underway to prepare government agencies and industries.

With the critical need to address security and satisfy latency, bandwidth, licensing and cost, companies have explored options, including optical wireless communication (OWC). For decades, NASA used a license-free wireless technology in its Laser Communications Relay Demonstration and the Orion Exploration Mission 2 Optical Communications program; the process uses low-power, eye-safe, infrared lasers in the terahertz spectrum. Ultimately, this OWC technology provides rapid data transmission via beams of light connecting from one telescope to another or point-to-point.

Many military applications have relied on OWC for decades to communicate securely over unknown and hostile terrain. Over the years, OWC has benefited from improvements in lasers, amplifiers, and detectors, along with commercial investment from more traditional defense and aerospace companies in the U.S., Japan, and Europe.

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