TY - JOUR
T1 - Audio Hotspot Attack
T2 - An Attack on Voice Assistance Systems Using Directional Sound Beams and its Feasibility
AU - Iijima, Ryo
AU - Minami, Shota
AU - Zhou, Yunao
AU - Takehisa, Tatsuya
AU - Takahashi, Takeshi
AU - Oikawa, Yasuhiro
AU - Mori, Tatsuya
N1 - Publisher Copyright:
© 2013 IEEE.
PY - 2021
Y1 - 2021
N2 - We propose a novel attack, called an 'Audio Hotspot Attack,' which performs an inaudible malicious voice command attack, by targeting voice assistance systems, e.g., smart speakers or in-car navigation systems. The key idea of the approach is to leverage directional sound beams generated from parametric loudspeakers, which emit amplitude-modulated ultrasounds that will be self-demodulated in the air. Our work goes beyond the previous studies of inaudible voice command attack in the following three aspects: (1) the attack can succeed on a long distance (3.5 meters in a small room, and 12 meters in a long hallway), (2) it can control the spot of the audible area by using two directional sound beams, which consist of a carrier wave and a sideband wave, and (3) the proposed attack leverages a physical phenomenon i.e., non-linearity in the air, to attack voice assistance systems. To evaluate the feasibility of the attack, we performed extensive in-lab experiments and a user study involving 20 participants. The results demonstrated that the attack was feasible in a real-world setting. We discussed the extent of the threat, as well as the possible countermeasures against the attack.
AB - We propose a novel attack, called an 'Audio Hotspot Attack,' which performs an inaudible malicious voice command attack, by targeting voice assistance systems, e.g., smart speakers or in-car navigation systems. The key idea of the approach is to leverage directional sound beams generated from parametric loudspeakers, which emit amplitude-modulated ultrasounds that will be self-demodulated in the air. Our work goes beyond the previous studies of inaudible voice command attack in the following three aspects: (1) the attack can succeed on a long distance (3.5 meters in a small room, and 12 meters in a long hallway), (2) it can control the spot of the audible area by using two directional sound beams, which consist of a carrier wave and a sideband wave, and (3) the proposed attack leverages a physical phenomenon i.e., non-linearity in the air, to attack voice assistance systems. To evaluate the feasibility of the attack, we performed extensive in-lab experiments and a user study involving 20 participants. The results demonstrated that the attack was feasible in a real-world setting. We discussed the extent of the threat, as well as the possible countermeasures against the attack.
KW - Internet of Things
KW - Voice assistance systems
KW - acoustics
KW - security
KW - ultrasonic
KW - voice commands attack
UR - http://www.scopus.com/inward/record.url?scp=85075382783&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85075382783&partnerID=8YFLogxK
U2 - 10.1109/TETC.2019.2953041
DO - 10.1109/TETC.2019.2953041
M3 - Article
AN - SCOPUS:85075382783
SN - 2168-6750
VL - 9
SP - 2004
EP - 2018
JO - IEEE Transactions on Emerging Topics in Computing
JF - IEEE Transactions on Emerging Topics in Computing
IS - 4
ER -