This article presents the concept of the encryption key generator on the basis of passive fiber optic components. Quantum random number generators (QRNG) are used to obtain the random number sequences used to securely encode information transmitted in the fiber track. The authors propose a different approach than the currently used random number generators based on beam splitting element, namely the construction of this type of system based on passive fiber optic components with the use of single-photon generation. The article presents the analysis of the generation of random number sequences as well as independently developed simulator generation of random sequences. It also contains a description of selected items and the reasons for selection as well as patterns of accomplished setup made in the Security Systems Group in Institute of Optoelectronics. The methodology of measuring generation randomness of quantum random number generator is described here, also certified system made by ID Quantique and propretiary solution is compared and results of measurements of this comparison are presented. The work also includes tests of the certified system Quantis by IDQ company and the system made by a team in terms of randomness generated within. These tests are important from the point of view of the certification of a generator system and assign it to the appropriate safety class. The measurement results are contained in the article.
This article presents the single photon fiber optic sensor for detecting interferences of the transmission line. With the growing popularity of the use of fiber optic communication systems, there is a need to protect transmission lines against unauthorized interference and data interception. Classical Quantum Key Distribution (QKD) allows to transfer quantum key and interrupt transmission when it detects interference. The use of proven as safe protocols BB84 in conjunction with currently used encryption techniques provide better data safety. However, due to lack of evidence on the safety of transmission using commercial QKD systems, their apply to the protection of classified information is currently impossible. Support these assumptions are carried out so far successful attacks on QKD systems. These statements do not mean impossibility of implementing these systems for the protection of classified information in the future. Our team proposes a solution consisting in transmitting information in fiber optic track with simultaneous implementation of a single photon sensor, developmentally impaired with the location of the interference place. The greatest yield of this method is to detect the intruder, who is unaware of its detection. To optimize and accelerate the testing, a simulation program that allows you to adjust the operating parameters of the sensor system and verification of performance of laboratory systems has been developed. Execution of simulation, helps in the selection of appropriate elements of the actual configuration and in comparison to obtained results. This work contains the results of the test operation of the system for disorders of mechanical and manual as well as performed simulations.
This paper presents tests of the active composite fence with razor tape module. Due to application of electro-magnetic and optical fiber sensors the fence becomes actively protected. This type of solution may be used to detect violations of peripheral areas [1]. Due to using composite materials the fence is lighter, cheaper and resistant to environmental conditions (including corrosion). What is the most important the composite fence system is transparent to electromagnetic waves. Another advantage of using composite material is the possibility of integration the fiber optic and electro-magnetic cable in the structure of the fence [2]. The durability of a composite is comparable to a standard metal fence. The paper presents test results of the sensors placed on the composite fence. This type of the fence system protection with alarm sensors integrated in its structure is unique in the world scale. Performed tests consisted of laboratory and field tests of modalmetric fiber optic sensor itself, laboratory and field tests of electro-magnetic sensor itself and field tests of both sensors combined. During the laboratory tests an electrodynamic shaker was used to excite the modalmetric sensor to an alarm state. Its excitation distance decreases with the frequency growth. The tests were made for different frequencies and different forces to imitate different fence violation e.g. climbing on it, cutting it or walking along it.
Access to the requested content is limited to institutions that have purchased or subscribe to SPIE eBooks.
You are receiving this notice because your organization may not have SPIE eBooks access.*
*Shibboleth/Open Athens users─please
sign in
to access your institution's subscriptions.
To obtain this item, you may purchase the complete book in print or electronic format on
SPIE.org.
INSTITUTIONAL Select your institution to access the SPIE Digital Library.
PERSONAL Sign in with your SPIE account to access your personal subscriptions or to use specific features such as save to my library, sign up for alerts, save searches, etc.