The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
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The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
Sistemas criptográficos leves para serviços fornecidos pela recentemente desenvolvida Internet das Coisas (IoT) estão sendo continuamente pesquisados. No entanto, os algoritmos criptográficos baseados em infraestrutura de chave pública (PKI) existentes são difíceis de aplicar aos serviços IoT fornecidos usando dispositivos leves. Portanto, estão sendo estudados sistemas de criptografia, autenticação e assinatura baseados em criptografia de chave pública sem certificado (CL-PKC), que são leves porque não usam os certificados dos algoritmos criptográficos baseados em PKI existentes. Dos vários sistemas criptográficos de chave pública, a criptografia de sinais é eficiente e garante integridade e confidencialidade. Recentemente, esquemas de criptografia de sinalização baseados em CL (CL-SC) têm sido intensamente estudados, e um protocolo de criptografia de sinalização multi-receptor (MRSC) para ambientes com múltiplos receptores, ou seja, que não envolvem comunicação ponta a ponta, foi proposto. No entanto, ao usar signcryption, a confidencialidade e a integridade podem ser violadas por ataques de substituição de chave pública. Neste artigo, desenvolvemos um esquema eficiente de MRSC baseado em CL (CL-MRSC) usando CL-PKC para ambientes IoT. Os esquemas de criptografia de sinais existentes não oferecem verificabilidade pública, o que é necessário se forem utilizadas assinaturas digitais, porque apenas o destinatário pode verificar a validade da mensagem; a autenticidade do remetente não é garantida por terceiros. Portanto, propomos um esquema CL-MRSC no qual os participantes da comunicação (como os gateways através dos quais as mensagens são transmitidas) podem verificar de forma eficiente e pública a validade das mensagens criptografadas.
Dae-Hwi LEE
Soonchunhyang University
Won-Bin KIM
Soonchunhyang University
Deahee SEO
Sangmyung University
Im-Yeong LEE
Soonchunhyang University
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Dae-Hwi LEE, Won-Bin KIM, Deahee SEO, Im-Yeong LEE, "An Efficient Public Verifiable Certificateless Multi-Receiver Signcryption Scheme for IoT Environments" in IEICE TRANSACTIONS on Information,
vol. E104-D, no. 11, pp. 1869-1879, November 2021, doi: 10.1587/transinf.2021NGP0012.
Abstract: Lightweight cryptographic systems for services delivered by the recently developed Internet of Things (IoT) are being continuously researched. However, existing Public Key Infrastructure (PKI)-based cryptographic algorithms are difficult to apply to IoT services delivered using lightweight devices. Therefore, encryption, authentication, and signature systems based on Certificateless Public Key Cryptography (CL-PKC), which are lightweight because they do not use the certificates of existing PKI-based cryptographic algorithms, are being studied. Of the various public key cryptosystems, signcryption is efficient, and ensures integrity and confidentiality. Recently, CL-based signcryption (CL-SC) schemes have been intensively studied, and a multi-receiver signcryption (MRSC) protocol for environments with multiple receivers, i.e., not involving end-to-end communication, has been proposed. However, when using signcryption, confidentiality and integrity may be violated by public key replacement attacks. In this paper, we develop an efficient CL-based MRSC (CL-MRSC) scheme using CL-PKC for IoT environments. Existing signcryption schemes do not offer public verifiability, which is required if digital signatures are used, because only the receiver can verify the validity of the message; sender authenticity is not guaranteed by a third party. Therefore, we propose a CL-MRSC scheme in which communication participants (such as the gateways through which messages are transmitted) can efficiently and publicly verify the validity of encrypted messages.
URL: https://global.ieice.org/en_transactions/information/10.1587/transinf.2021NGP0012/_p
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@ARTICLE{e104-d_11_1869,
author={Dae-Hwi LEE, Won-Bin KIM, Deahee SEO, Im-Yeong LEE, },
journal={IEICE TRANSACTIONS on Information},
title={An Efficient Public Verifiable Certificateless Multi-Receiver Signcryption Scheme for IoT Environments},
year={2021},
volume={E104-D},
number={11},
pages={1869-1879},
abstract={Lightweight cryptographic systems for services delivered by the recently developed Internet of Things (IoT) are being continuously researched. However, existing Public Key Infrastructure (PKI)-based cryptographic algorithms are difficult to apply to IoT services delivered using lightweight devices. Therefore, encryption, authentication, and signature systems based on Certificateless Public Key Cryptography (CL-PKC), which are lightweight because they do not use the certificates of existing PKI-based cryptographic algorithms, are being studied. Of the various public key cryptosystems, signcryption is efficient, and ensures integrity and confidentiality. Recently, CL-based signcryption (CL-SC) schemes have been intensively studied, and a multi-receiver signcryption (MRSC) protocol for environments with multiple receivers, i.e., not involving end-to-end communication, has been proposed. However, when using signcryption, confidentiality and integrity may be violated by public key replacement attacks. In this paper, we develop an efficient CL-based MRSC (CL-MRSC) scheme using CL-PKC for IoT environments. Existing signcryption schemes do not offer public verifiability, which is required if digital signatures are used, because only the receiver can verify the validity of the message; sender authenticity is not guaranteed by a third party. Therefore, we propose a CL-MRSC scheme in which communication participants (such as the gateways through which messages are transmitted) can efficiently and publicly verify the validity of encrypted messages.},
keywords={},
doi={10.1587/transinf.2021NGP0012},
ISSN={1745-1361},
month={November},}
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TY - JOUR
TI - An Efficient Public Verifiable Certificateless Multi-Receiver Signcryption Scheme for IoT Environments
T2 - IEICE TRANSACTIONS on Information
SP - 1869
EP - 1879
AU - Dae-Hwi LEE
AU - Won-Bin KIM
AU - Deahee SEO
AU - Im-Yeong LEE
PY - 2021
DO - 10.1587/transinf.2021NGP0012
JO - IEICE TRANSACTIONS on Information
SN - 1745-1361
VL - E104-D
IS - 11
JA - IEICE TRANSACTIONS on Information
Y1 - November 2021
AB - Lightweight cryptographic systems for services delivered by the recently developed Internet of Things (IoT) are being continuously researched. However, existing Public Key Infrastructure (PKI)-based cryptographic algorithms are difficult to apply to IoT services delivered using lightweight devices. Therefore, encryption, authentication, and signature systems based on Certificateless Public Key Cryptography (CL-PKC), which are lightweight because they do not use the certificates of existing PKI-based cryptographic algorithms, are being studied. Of the various public key cryptosystems, signcryption is efficient, and ensures integrity and confidentiality. Recently, CL-based signcryption (CL-SC) schemes have been intensively studied, and a multi-receiver signcryption (MRSC) protocol for environments with multiple receivers, i.e., not involving end-to-end communication, has been proposed. However, when using signcryption, confidentiality and integrity may be violated by public key replacement attacks. In this paper, we develop an efficient CL-based MRSC (CL-MRSC) scheme using CL-PKC for IoT environments. Existing signcryption schemes do not offer public verifiability, which is required if digital signatures are used, because only the receiver can verify the validity of the message; sender authenticity is not guaranteed by a third party. Therefore, we propose a CL-MRSC scheme in which communication participants (such as the gateways through which messages are transmitted) can efficiently and publicly verify the validity of encrypted messages.
ER -