59,481 research outputs found
Towards generic satellite payloads: software radio
Satellite payloads are becoming much more complex with the evolution towards multimedia applications. Moreover satellite lifetime increases while standard and services evolve faster, necessitating a hardware platform that can evolves for not developing new systems on each change. The same problem occurs in terrestrial systems like mobile networks and a foreseen solution is the software defined radio technology. In this paper we describe a way of introducing this concept at satellite level to offer to operators the required flexibility in the system. The digital functions enabling this technology, the hardware components implementing the functions and the reconfiguration processes are detailed. We show that elements of the software radio for satellites exist and that this concept is feasible
POWER-SUPPLaY: Leaking Data from Air-Gapped Systems by Turning the Power-Supplies Into Speakers
It is known that attackers can exfiltrate data from air-gapped computers
through their speakers via sonic and ultrasonic waves. To eliminate the threat
of such acoustic covert channels in sensitive systems, audio hardware can be
disabled and the use of loudspeakers can be strictly forbidden. Such audio-less
systems are considered to be \textit{audio-gapped}, and hence immune to
acoustic covert channels.
In this paper, we introduce a technique that enable attackers leak data
acoustically from air-gapped and audio-gapped systems. Our developed malware
can exploit the computer power supply unit (PSU) to play sounds and use it as
an out-of-band, secondary speaker with limited capabilities. The malicious code
manipulates the internal \textit{switching frequency} of the power supply and
hence controls the sound waveforms generated from its capacitors and
transformers. Our technique enables producing audio tones in a frequency band
of 0-24khz and playing audio streams (e.g., WAV) from a computer power supply
without the need for audio hardware or speakers. Binary data (files,
keylogging, encryption keys, etc.) can be modulated over the acoustic signals
and sent to a nearby receiver (e.g., smartphone). We show that our technique
works with various types of systems: PC workstations and servers, as well as
embedded systems and IoT devices that have no audio hardware at all. We provide
technical background and discuss implementation details such as signal
generation and data modulation. We show that the POWER-SUPPLaY code can operate
from an ordinary user-mode process and doesn't need any hardware access or
special privileges. Our evaluation shows that using POWER-SUPPLaY, sensitive
data can be exfiltrated from air-gapped and audio-gapped systems from a
distance of five meters away at a maximal bit rates of 50 bit/sec
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