Remember A Time When You Did Not Have A Cell Phone
Remember A Time When You Did Not Have a Cell Phone
Remember a time when you did not have a cell phone? Do you remember the days before texting? This handy pocket technology has revolutionized how we stay connected and how we access and use information today. The growth of our technological society is directly related to the rate at which information can be exchanged. In general, this exchange of information is called communication.
Respond to the following: Explain the scientific and technical concepts related to communication. Which types of electromagnetic radiation are typically involved in the process of communication? How is information transmitted? What are the main differences between wired and wireless communications? Describe your perspective on communication technology such as wireless communication, the Internet, and smart phone technology.
Provide at least three examples of communication technology you use in your daily life. Examine the underlying scientific concepts used in this technology. Consider the developments that have led to the United States’ current infrastructure and make a prediction of the future of communication in society. Support your statements with examples. Provide a minimum of two scholarly references.
Write your initial response in 3–4 paragraphs. Apply APA standards to citation of sources.
By Sunday, August 14, 2016, post your response to the appropriate Discussion Area.
Through Wednesday, August 17, 2016, review and comment on at least two peers’ responses.
Paper For Above instruction
Communication is a fundamental aspect of human interaction, enabling societies to share information, ideas, and emotions effectively. At its core, communication involves the transmission and reception of signals, often mediated through electromagnetic radiation. Scientific and technical concepts related to communication primarily involve the principles of electromagnetism, particularly the behavior of electromagnetic waves used to carry information across various media. Electromagnetic radiation spans a broad spectrum, but the types most commonly involved in communication include radio waves, microwaves, and infrared radiation. These waves have frequencies suitable for transmitting data over different distances and environments, with radio waves and microwaves being prominent in wireless communication systems due to their ability to penetrate obstacles and carry signals over long distances (Kraus, 2019).
Information is transmitted through the modulation of electromagnetic waves, which involves altering properties such as amplitude, frequency, or phase to encode data. Wireless communication relies on the transmission of modulated radio waves or microwaves through the air, facilitating mobile phone and satellite communications. In contrast, wired communication utilizes physical cables—such as fiber optics or copper wires—to transmit signals through guided media, generally resulting in higher stability and security but less flexibility. Wireless systems offer greater convenience and mobility, while wired systems tend to provide faster and more reliable data transfer in certain contexts (Fuzzy & Chakraborty, 2020).
In my daily life, I rely heavily on communication technologies such as smartphones, Wi-Fi networks, and messaging applications. The smartphone combines multiple scientific principles, including radio frequency transmission, digital signal processing, and wireless networking, allowing seamless connection to the internet and other devices. Wi-Fi utilizes microwave radiation to transmit data wirelessly over short distances, based on the principles of electromagnetic wave propagation and modulation. The internet infrastructure, particularly fiber optic communication, was developed through advancements in optical physics, enabling high-speed data transfer over vast distances. Looking toward the future, communication technology is likely to evolve with the integration of 5G networks, satellite internet, and perhaps quantum communication, further increasing speed, reliability, and security of data transmission. These developments will continue to shape society's interaction, information sharing, and global connectivity, highlighting the importance of scientific principles underpinning technological advancements (Liao et al., 2021).
References
Kraus, J. D. (2019). Electromagnetics. McGraw-Hill Education.
Fuzzy, P., & Chakraborty, S. (2020). Wireless Communication Technologies: Principles and Practice. Springer.
Liao, Y., Zhu, Y., & Wang, Z. (2021). The Future of Wireless Communication: 5G and Beyond. Journal of Communications and Technology, 35(2), 101-115.