The various advanced technologies incorporated in the existing power system to operate in smarter and to provide continuity of power supply without any disturbances. Still, it was few threats that disrupting the electrical network to manage the power demand such as: complexity of the power grid; vulnerability to faults; energy efficiency; and renewable energy integration. The above challenges indicate the perception of smart grid (SG). The smart grid design is economic, competent, intelligent and secured grid was needed to manage the above-mentioned issues. Self-healing is the most essential characteristics of a smart grid. The implementation of self-healing control strategy in the smart grid is one of the prolong challenge. It is the capability of the power system network to restore naturally the network when the fault occurs. It gives primary assurance to the smart grid protection. Apart from this, the implementation of various control strategies assist accomplishing the safe functioning, enhancing the stability of the grid. This paper presents the self-healing control strategy in the context of smart grid power systems. The significant advancements developed in the transmission, distribution, micro grid as a result of power electronics converters presented. Then, the information and communication technologies, software tools and measurements which can be employed for winning crucial smart grid self-healing action will be discussed.

将各种先进技术融入现有电力系统，以更智能地运行，并在没有任何干扰的情况下提供电力供应的连续性。尽管如此，破坏电网以管理电力需求的威胁仍然很少，例如：电网的复杂性；易受故障影响；能源效率; 和可再生能源整合。上述挑战表明了对智能电网（SG）的认知。智能电网的设计是经济的、有能力的、智能的和安全的电网是管理上述问题所必需的。自我修复是智能电网最基本的特性。在智能电网中实施自愈控制策略是长期的挑战之一。是电力系统网络在故障发生时自然恢复网络的能力。为智能电网保护提供了首要保障。除此之外，各种控制策略的实施有助于实现安全运行，增强电网的稳定性。本文介绍了智能电网电力系统背景下的自愈控制策略。由于电力电子转换器的出现，输电、配电、微电网取得了重大进展。然后，将讨论可用于赢得关键智能电网自愈行动的信息和通信技术、软件工具和测量。本文介绍了智能电网电力系统背景下的自愈控制策略。由于电力电子转换器的出现，输电、配电、微电网取得了重大进展。然后，将讨论可用于赢得关键智能电网自愈行动的信息和通信技术、软件工具和测量。本文介绍了智能电网电力系统背景下的自愈控制策略。由于电力电子转换器的出现，输电、配电、微电网取得了重大进展。然后，将讨论可用于赢得关键智能电网自愈行动的信息和通信技术、软件工具和测量。