Enabling security in software-defined wireless sensor networks for internet of things

Toledo, Cézar Murilo Geronaso de; Oliveira, Doriedson A. G.; Simplício, Marcos A.; Margi, Cintia Borges

doi:10.5753/errc.2020.15198

Cited by 2 publications

(6 citation statements)

References 11 publications

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“…Alves et al proposed a wireless secure SDN-based communication for TinySDN that supports end-to-end key distribution and secure node admission. de Toledo et al [39] proposed a security framework for SDWSNs, which can establish end-to-end security between the nodes and SDN Controller. However, neither of them takes into account threats to the topology information, such as the Sybil attacks among the nodes and Controller.…”

Section: Communication Security In Sdwsnsmentioning

confidence: 99%

“…Node admission is a process that allows new nodes to be authenticated and trusted by the sinks and Controller [13]. Whether it is to send topology reports safely or use security services, secure channels must be established with the Controller and the selected sink [39]. To protect end-to-end communication security, our modified IBAKE protocol could achieve authentication and key establishment between two remote nodes, such as the sink and the node.…”

Section: Node Admission and Keymentioning

confidence: 99%

“…The Controller periodicity collects the underlying topology messages to form the network topology [11]. Although this is a promising approach, one of the weaknesses of SDWSNs is the lack of authentication and encryption mechanisms [12]. SDWSNs use the open wireless link to transmit the data and control packets [13] which makes topology messages vulnerable to eavesdropping and tampering attacks.…”

Section: Introductionmentioning

confidence: 99%

“…Any new node can join the network, which may also lead to many kinds of attacks, such as man-in-the-middle and replay attacks. However, the security of SDWSN topology control has not received enough attention [12,14].…”

Section: Introductionmentioning

confidence: 99%

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Securing Topology Control in SDWSNs Using Identity‐Based Cryptography

Wang¹,

Liu²,

Liu³

et al. 2023

Journal of Sensors

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In software-defined wireless sensor networks (SDWSNs), topology control is a fundamental procedure to maintain the global network topology. However, the open wireless channels of SDWSNs make it possible for an attacker to eavesdrop, replay, or modify the topology messages, thus posing a great threat to the network operations. The security of SDWSN topology control has not received enough attention yet. Identity-based cryptography (IBC) may be fitter for SDWSNs due to its capability of generating the public key from the node identity directly, compared with traditional cryptography. In particular, identity-based combined encryption and signature cryptography (IBCES) could encrypt and sign the messages using the same identity. As such, to secure the confidentiality, integrity, and authentication of topology information, we put forward a secure topology control mechanism based on IBCES. First, we use an identity-based encryption authenticated key agreement scheme to implement the authentication of neighbor nodes and hop-to-hop verification via secure neighbor discovery and topology discovery processes. Then through the node admission and key establishment process, the end-to-end secure channels are established between the nodes, sinks, and Controller. Finally, secure topology collection and management processes supporting flat and hierarchical network structures are designed to guarantee the security of topology information. Theoretical analysis shows that our methods could satisfy the security needs of SDWSN topology control and resist several security attacks. The experimental results indicate that our mechanisms are suitable for SDWSNs.

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Section: Communication Security In Sdwsnsmentioning

confidence: 99%

Section: Node Admission and Keymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Securing Topology Control in SDWSNs Using Identity‐Based Cryptography

Wang¹,

Liu²,

Liu³

et al. 2023

Journal of Sensors

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“…El diseño en [18] presenta un discriminador implementado por filtro rechaza bandas, con cuatro ramas paralelas para generar 4-bits de identificación. Este diseño opera en la banda de frecuencia de 2 a 4 GHz con una resolución de 62.5 MHz.…”

Section: Sistemas De Medición De Frecuencia Instantáneaunclassified

Dispositivos de medición de frecuencia reconfigurables = Reconfigurable frequency measurement devices

Espinosa Espinosa

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This thesis presents reconfigurable microwave discriminators used for the development of reconfigurable measurement circuits with high miniaturization, low power consumption, reduced weight and cost. The concept is demonstrated by the design and manufacture of several microwave discriminator topologies to generate 2 and 4 bits used for frequency identification. These topologies are implemented with transmission lines (microstrip and coplanar waveguides), solid state technology, and micro mechanical-electro-systems MEMS. Three reconfigurable microwave discriminator topologies are presented; the first topology generates 2-bits of frequency identification, the second topology generates 4-bit of frequency identification. These topologies use solid state technology (PIN diodes), microstrip transmission lines and operate in the frequency bands L and S. The third topology uses coplanar waveguides and two SPQT switches; each switch of the device is integrated in a RF-MEMS SPQT chip. This topology operates in the frequency bands C, X and Ku. Finally, the last topology presented in this work is the design of a MEMS phase shifter, which generates a phase shift of 180°. This topology uses slotline transmission lines and operates in the frequency band Ka. This phase shifter allows developing reconfigurable microwave discriminators with high miniaturization and reduced weight. En esta tesis se presenta el concepto de discriminadores de microondas reconfigurables de dos puertos para el desarrollo de sistemas de medición de frecuencia reconfigurables de alta miniaturización, peso y costo reducido. Este concepto es comprobado con el diseño y fabricación de varias topologías de discriminadores de microondas para generar 2 y 4 bits de identificación de frecuencia, implementados con líneas de transmisión microstrip y coplanar waveguide, y tecnología de estado sólido, y sistemas micro-electro-mecánicos MEMS. Se presentan tres topologías de discriminadores de microondas reconfigurables; uno genera 2 bits de identificación y los dos restantes generan 4 bits de identificación. Dos topologías utilizan tecnología de estado sólido (diodos PIN), líneas de transmisión microstrip y operan en la banda de frecuencia L y S. La última topología usa interruptores SPQT integrados en chips RF-MEMS, líneas de transmisión coplanar y opera en las bandas de operación C, X y Ku. Finalmente, se presenta el diseño de un defasador implementado con tecnología MEMS para generar un corrimiento de fase de 180°. Esta topología utiliza líneas de transmisión tipo slotline y opera en la banda Ka. Este defasador permite generar discriminadores de microondas reconfigurables con alta miniaturización, y peso reducido

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Enabling security in software-defined wireless sensor networks for internet of things

Cited by 2 publications

References 11 publications

Securing Topology Control in SDWSNs Using Identity‐Based Cryptography

Securing Topology Control in SDWSNs Using Identity‐Based Cryptography

Dispositivos de medición de frecuencia reconfigurables = Reconfigurable frequency measurement devices

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