Radar eavesdropping: Your smartphone’s tiny vibrations could reveal private conversations

  • Researchers at Penn State demonstrated that millimeter-wave radar can detect microscopic vibrations (7 micrometers) from smartphone speakers, allowing partial reconstruction of conversations from up to 10 feet away—without hacking or breaching encryption.
  • Using OpenAI’s Whisper, the team trained AI to interpret radar-captured vibrations, achieving 60 percent accuracy at 20 inches and 2-4 percent at 10 feet. Even fragmented data can reveal sensitive details (e.g., credit card numbers) if context is known.
  • Corporate spies, identity thieves or malicious actors could exploit this method without telecom cooperation. Tests on Samsung and OnePlus phones showed 40 percent accuracy at 3 feet despite natural hand movements.
  • Proposed countermeasures include vibration-masking motors, sound-absorbing materials, and AI-adjusted audio frequencies to confuse radar sensors. Manufacturers are urged to act before the technique becomes widespread.
  • The study highlights how advancing technology (e.g., AI, radar) erodes privacy via physical side channels. Recommendations include avoiding sensitive calls in public and advocating for hardware-level security upgrades.

That confidential phone call about your bank details or medical records may no longer be as private as you assume. Researchers at Penn State University have demonstrated that commercially available radar technology can remotely detect and partially reconstruct smartphone conversations by capturing microscopic vibrations from a phone’s speaker — movements so small they measure just 7 micrometers, invisible and inaudible to humans. Published in the Proceedings of WiSec 2025, the study reveals how attackers could exploit this method to intercept conversations from up to 10 feet away, raising urgent concerns about digital privacy in an era of advancing surveillance.

How radar turns into a spy tool

Radar, traditionally used for tracking aircraft or assisting self-driving cars, operates by bouncing radio waves off objects and measuring their reflections. While typically employed to detect large movements, modern millimeter-wave radar can pick up minute vibrations — like those produced by a smartphone’s speaker during a call. The Penn State team’s system, dubbed WirelessTap, exploits this by analyzing the subtle tremors in a phone’s casing caused by sound waves. (Related: Amazon’s AI wearable acquisition: Convenience or surveillance?.)

Unlike hacking or breaking encryption, this method bypasses digital security entirely. It’s akin to spying on a conversation by observing ripples in a glass of water placed near a speaker. The radar only requires a direct line of sight to the phone — no malware, no network intrusion.

From vibrations to words: AI’s role in decoding speech

The vibrations alone are not enough to reconstruct full conversations. To translate the distorted signals into intelligible speech, researchers adapted OpenAI’s Whisper, an advanced AI speech recognition model. By training Whisper on synthetic and real radar-captured audio, they achieved partial transcription — enough to extract key phrases, numbers or sensitive keywords.

At close range (20 inches), accuracy reached nearly 60 percent, dropping to just 2-4 percent at 10 feet. While that may seem low, even fragmented data can be dangerous. If an attacker already knows the context of a conversation — such as a banking call — they can fill in the gaps, much like lip-readers infer missing words.

Real-world risks: Who could exploit this?

The implications are alarming. Corporate spies could eavesdrop on confidential business calls. Identity thieves might snatch credit card numbers or passwords. Unlike traditional wiretapping, this method requires no cooperation from telecom providers — just a radar device and AI software.

The Penn State team tested three smartphones (Samsung Galaxy S20, Galaxy A22 and OnePlus 9 Pro) and found varying susceptibility. Even when a user held the phone naturally, introducing movement and interference, the system still achieved 40 percent accuracy at three feet — enough to capture critical details.

Defending against wireless eavesdropping

While the immediate threat is limited — requiring specialized equipment and ideal conditions — the researchers warn that radar technology is becoming smaller, cheaper and more accessible. To counter this, they propose several defenses:

  • Vibration masking: Adding small motors to create “noise” that drowns out real speech vibrations.
  • Material dampening: Using sound-absorbing materials around the phone’s speaker to minimize detectable tremors.
  • AI countermeasures: Adjusting audio output frequencies to confuse radar sensors without affecting call quality.

Manufacturers must act before this technique becomes widespread. As lead researcher Suryoday Basak noted, “By understanding what is possible, we can help the public be aware of the potential risks.”

A broader warning: Privacy in the age of AI surveillance

This discovery underscores a disturbing trend: as technology advances, so do the tools for invasion. From facial recognition to AI-powered voice analysis, privacy is under siege. The Penn State study serves as a wake-up call — even encrypted calls can be compromised through physical side channels.

For now, the best defense is awareness. Avoid sensitive calls in public spaces where radar devices could be concealed. Advocate for hardware-level security improvements from smartphone makers. And remember: In the digital age, privacy is no longer guaranteed — it must be fought for.

Watch this discussion on surveillance capitalism, AI and Big Brother rising.

This video is from the Crrow777 Radio channel on Brighteon.com.

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Sources include: 

Studyfinds.org

Interestingengineering.com

psu.edu

Brighteon.com

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