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Ethenet and wireless network
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Plăcile de rețea (Network Interface Cards-NICs) conectează un echipament la rețea. Plăcile de rețea Ethernet sunt folosite pentru o conexiune cablată, în timp ce plăcile de rețea WLAN (Wireless Local Area Network) sunt folosite pentru wireless. Un echipament cu utilizator final ar putea include unul sau ambele tipuri de plăci de rețea. De exemplu, o imprimantă de rețea poate avea doar o placă de rețea Ethernet, așadar, trebuie să se conecteze la rețea printr-un cablu Ethernet. Alte echipamente, precum tabletele sau telefoanele pot conține o placă de rețea WLAN și trebuie să folosească o conexiune wireless. Layer-ul Fizic Layer-ul fizic de la OSI furnizează mijloacele de transport a biților care realizează un frame de data link în mediul de rețea. Acest layer acceptă un frame complet de la layer-ul data link și îl codifică sub forma unor serii de semnale care sunt transmise în mediul local. Biții codificați care comprimă un frame sunt primiți fie de un echipament final, fie de unul intermediar. Procesul prin care trec datele de la nodul sursă la nodus destinație este: • Datele utilizatorului sunt segmentate de layer-ul transport, plasate în pachete de către layer-ul rețea, iar apoi încapsulate sub formă de frame-uri de către layer-ul data link. • Layer-ul fizic codifică frame-urile și creează semnalele undelor electrice, optice și radio care reprezintă biții în fiecare frame. • Aceste semnale sunt trimise în mediu pe rând. • Nodul destinație preia aceste semnale individuale de la nivelul fizic, le transformă în reprezentare binară și transmit biții la nivelul superior, data link, sub forma unui frame. Mediul layer-ului Fizic Există trei forme de bază ale mediului de rețea. Layer-ul fizic produce reprezentarea și gruparea biților pentru fiecare mediu, după cum urmează: • Cablu de cupru: Semnalele sunt modele ale pulsurilor electrice. • Cablul cu fibră optică: Semnalele sunt modele de lumină. • Wireless: Semnalele sunt modele ale transmisiunilor cu microunde. Figura afișează exemple de semnalizare pentru cupru, fibră optică și wireless. Pentru a activa interoperabilitatea layer-ului fizic, toate aspectele acestor funcții sunt guvernate de organizațiile de standardizare. Standardele Layer-ului Fizic Protocoalele și operațiile layerelor superioare din OSI sunt efectuate în software proiectat de ingineri și oameni de știință. De exemplu, serviciile și protocoalele din suita TCP/IP sunt definite de Internet Engineering Task Force (IETF) în RFC-uri așa cum se arată în Figura 1. Layer-ul fizic constă în circuite electronice, mediu și conectori dezvoltați de ingineri. Așadar, este corespunzător ca standardele care guvernează acest hardware să fie definite de orgnizațiile relevante din domeniul ingineriei și electronicii. Există mai multe organizații naționale și internaționale diferite, organizații guvernamentale de reglementare și companii private implicate în stabilirea și menținerea standardelor layer-ului fizic. De exemplu, hardware-ul layer-ului fizic, mediul, codificarea și standardele de semnalizare sunt definite și guvernate de către: • International Organization for Standardization (ISO) • Telecommunications Industry Association/Electronic Industries Association (TIA/EIA) • International Telecommunication Union (ITU) • American National Standards Institute (ANSI) • Institute of Electrical and Electronics Engineers (IEEE) • Autoritățile de reglementare națională a telecomunicațiilor, inclusiv Federal Communication Commission (FCC) din USA și European Telecommunications Standards Institute (ESTI) Pe lângă acestea, există grupuri de standardizare a cablărilor regionale precum CSA (Canadian Standards Association), CENELEC (European Committee for Electrotechnical Standardization) și JSA/JSI (Japanese Standards Association), care dezvoltă specificații locale. Figura 2 listează contribuitorii principali și câteva standarde relevante ale layer-ului fizic.The effects of gibberellins and ethene on plant growth and developmentUnderstanding of network and internet, network core, Understanding of Delay, Loss and Throughput in the packet switching network, Network Models- OSI Reference Model, TCP/IP Model,Introduction to data link layer services, error-detection and correction techniques, Multiple access protocols, addressing, Ethernet, switches, Virtual LAN,Introduction to forwarding and routing, Network Service models, Virtual and Datagram networks, study of router, IP protocol, IPV4 and IPV6 addressing in the Internet, Routing algorithms, Broadcast and Multicast routing,Introduction and transport layer services, Multiplexing and Demultiplexing, Connectionless transport (UDP), Principles of reliable data transfer, Connection- oriented transport (TCP), Congestion control, TCP congestion control.4.32C know that ethanol can be manufactured by: • reacting ethene with steam in the presence of a phosphoric acid catalyst at a temperature of about 300 ºC and a pressure of about 60–70 atm • the fermentation of glucose, in the absence of air, at an optimum temperature of about 30 ºC and using the enzymes in yeast 4.33C understand the reasons for fermentation, in the absence of air, and at an optimum temperatureCommon On-Chip Peripherals: Serial Communication Interfaces: UART (Universal Asynchronous Receiver/Transmitter): Enables serial communication for data transmission and reception. SPI (Serial Peripheral Interface): Facilitates fast, synchronous serial communication with external devices. I2C (Inter-Integrated Circuit): Another common protocol for serial communication, often used for connecting sensors and other peripherals. Timers and Counters: General Purpose Timers: Used for generating precise time delays and measuring intervals. Real-Time Clock (RTC): Keeps track of time even when the DSP is in a low-power state. Watchdog Timer: Monitors the DSP's operation and resets it if it detects a fault. Interrupt Controllers: Interrupts: Allow peripherals to signal the DSP when an event occurs, enabling efficient and responsive system operation. Memory Management: DMA (Direct Memory Access): Enables data transfer between memory and peripherals without CPU intervention, improving efficiency. On-Chip Memory: Includes RAM, ROM, and flash memory for storing data and code. Audio/Video Interfaces: DAC (Digital-to-Analog Converter): Converts digital signals to analog signals for audio output. ADC (Analog-to-Digital Converter): Converts analog signals to digital signals for processing. I/O Ports: GPIO (General Purpose Input/Output): Provides flexible control over external devices. Ethernet MAC (Media Access Controller): Enables network connectivity. Other Peripherals: LCD Controller: For displaying information on LCD screens. USB Interface: For connecting to USB devices. CAN (Controller Area Network): For communication in automotive and industrial applications. Organic Nomenclature. What are aliphatic compounds or aliphatic hydrocarbons? An aliphatic compound or aliphatic hydrocarbon is an organic compound containing hydrogen and carbon atoms that are usually linked together in chains that are straight. The term Aliphatic has been derived from the Greek word “Aleiphar” which translates to “fat”. It is used to describe hydrocarbons that are obtained by the chemical degradation of oils or fats. What are aliphatic compounds or aliphatic hydrocarbons? The simplest organic compounds are those composed of only two elements: carbon and hydrogen. These compounds are called hydrocarbons. Hydrocarbons are separated into two types: aliphatic hydrocarbons and aromatic hydrocarbons. Aliphatic hydrocarbons are hydrocarbons based on chains of C atoms. There are three types of aliphatic hydrocarbons: Alkanes are aliphatic hydrocarbons with only single covalent bonds. Alkenes are hydrocarbons that contain at least one C–C double bond, and alkynes are hydrocarbons that contain a C–C triple bond. Occasionally, we find an aliphatic hydrocarbon with a ring of C atoms; these hydrocarbons are called cycloalkanes (or cycloalkenes or cycloalkynes). The simplest alkanes have their C atoms bonded in a straight chain; these are called normal alkanes. They are named according to the number of C atoms in the chain. The smallest alkane is methane: molecule is three dimensional, with the H atoms in the positions of the four corners of a tetrahedron. The diagrams representing alkanes are called structural formulas because they show the structure of the molecule. As molecules get larger, structural formulas become more and more complex. One way around this is to use a condensed structural formula, which lists the formula of each C atom in the backbone of the Molecule. The condensed formulas show hydrogen atoms right next to the carbon atoms to which they are attached, as illustrated for butane: The ultimate condensed formula is a line-angle formula (or line drawing) , in which carbon atoms are implied at the corners and ends of lines, and each carbon atom is understood to be attached to enough hydrogen atoms to give each carbon atom four bonds. For example, we can represent pentane (CH3CH2CH2CH2CH3) and isopentane [(CH3)2CHCH2CH3] as follows: Unsaturated Hydocarbons: Alkenes and Alkynes Alkenes Organic compounds that contain one or more double or triple bonds between carbon atoms are described as unsaturated. Unsaturated hydrocarbons have less than the maximum number of H atoms possible. Unsaturated hydrocarbon molecules that contain one or more double bonds are called alkenes. Carbon atoms linked by a double bond are bound together by two bonds, one σ bond and one π bond. Double and triple bonds give rise to a different geometry around the carbon atom that participates in them, leading to important differences in molecular shape and properties. The differing geometries are responsible for the different properties of unsaturated versus saturated fats. Naming Alkenes and Alkynes Alkenes and alkynes are named in a similar fashion. The biggest difference is that when identifying the longest carbon chain, it must contain the C–C double or triple bond. Furthermore, when numbering the main chain, the double or triple bond gets the lowest possible number. This means that there may be longer or higher-numbered substituents than may be allowed if the molecule were an alkane. For example, this molecule is 2,4-dimethyl-3-heptene (note the number and the hyphens that indicate the position of the double bond). Unsaturated Hydocarbons: Alkenes and Alkynes Unsaturated Hydocarbons: Alkenes and Alkynes Alkynes Hydrocarbon molecules with one or more triple bonds are called alkynes; they make up another series of unsaturated hydrocarbons. Two carbon atoms joined by a triple bond are bound together by one σ bond and two π bonds. The sp-hybridized carbons involved in the triple bond have bond angles of 180°, giving these types of bonds a linear, rod-like shape. The simplest member of the alkyne series is ethyne, C2H2, commonly called acetylene. The Lewis structure for ethyne, a linear molecule, is: Properties of Unsaturated Hydocarbons: Alkenes and Alkynes Ethylene (the common industrial name for ethene) is a basic raw material in the production of polyethylene and other important compounds. Over 135 million tons of ethylene were produced worldwide in 2010 for use in the polymer, petrochemical, and plastic industries. Ethylene is produced industrially in a process called cracking, in which the long hydrocarbon chains in a petroleum mixture are broken into smaller molecules. Halogens can also react with alkenes and alkynes, but the reaction is different. In these cases, the halogen reacts with the C–C double or triple bond and inserts itself onto each C atom involved in the multiple bonds. This reaction is called an addition reaction. One example is Properties of Unsaturated Hydocarbons: Alkenes and Alkynes Hydrogen can also be added across a multiple bond; this reaction is called a hydrogenation reaction. In this case, however, the reaction conditions may not be mild; high pressures of H2 gas may be necessary. A platinum or palladium catalyst is usually employed to get the reaction to proceed at a reasonable pace: CH2=CH2+H2→metalcatalystCH3CH3 CH2=CH2+H2→metalcatalystCH3CH3. Ethernet cabling , rj45 , crimping tool, color coding Ethernet - Demarcation devices