Tabla de Contenidos: “…Vertical 3D Memory Technologies; Contents; Acknowledgments; 1 Basic Memory Device Trends Toward the Vertical; 1.1 Overview of 3D Vertical Memory Book; 1.2 Moore's Law and Scaling; 1.3 Early RAM 3D Memory; 1.3.1 SRAM as the First 3D Memory; 1.3.2 An Early 3D Memory-The FinFET SRAM; 1.3.3 Early Progress in 3D DRAM Trench and Stack Capacitors; 1.3.4 3D as the Next Step for Embedded RAM; 1.4 Early Nonvolatile Memories Evolve to 3D; 1.4.1 NOR Flash Memory-Both Standalone and Embedded; 1.4.2 The Charge-Trapping EEPROM; 1.4.3 Thin-Film Transistor Takes Nonvolatile Memory into 3D…”

Tabla de Contenidos: “…2.1.2 The 16F84A 2.1.3 A caution on upgrades; 2.2 An architecture overview of the 16F84A; 2.2.1 The Status register; 2.3 A review of memory technologies; 2.3.1 Static RAM (SRAM); 2.3.2 EPROM (Erasable Programmable Read-Only Memory); 2.3.3 EEPROM (Electrically Erasable Programmable Read-Only Memory); 2.3.4 Flash; 2.4 The 16F84A memory; 2.4.1 The 16F84A program memory; 2.4.2 The 16F84A data and Special Function Register memory ('RAM'); 2.4.3 The Configuration Word; 2.4.4 EEPROM; 2.5 Some issues of timing; 2.5.1 Clock oscillator and instruction cycle; 2.5.2 Pipelining; 2.6 Power-up and Reset…”

Tabla de Contenidos: “…The PIC Microcontroller; Early PIC Variants; Oscillator Connections; Reset Circuit; Internal Architecture; Input/Output Operations; The 16C5x Instruction Set; Simple Programming Examples; Members of the PIC16C5x family; I/O Port Structures; Timing; The Rest of the Family; PICs with ADC; Analogue to Digital Converter Programming; Interrupts on the PIC; Stack; PIC16C84 with EEPROM Management; The Watchdog Timer; Power Down Mode; Subroutines vs Macros…”

Tabla de Contenidos: “…; Assumptions About You; What You Need; An Atmel-Based Microcontroller Card; Types of Memory; Flash Memory; SRAM; EEPROM; Making the Choice; Board Size; Input/Output (I/O) Pins; Breadboard; Miscellaneous Parts; Installing and Verifying the Software; Verifying the Hardware; Attaching the USB Cable; Selecting Your μc Board in the Integrated Development Environment; Port Selection…”

Tabla de Contenidos: “…""In-Wall Transmitter Modules""""Motion Sensors""; ""Gateways and Other Exotic Devices""; ""Computer Control""; ""Heyu""; ""Configuration""; ""Sending Messages""; ""Receiving Messages""; ""Programming the EEPROM""; ""Z-Wave""; ""System Design""; ""Bypassing NDAs""; ""Open Z-Wave""; ""LinuxMCE""; ""ZigBee""; ""Linux Software""; ""The Differences with Z-Wave""; ""C-Bus""; ""About C-Bus""; ""Differences Between X10 and C-Bus""; ""Devices""; ""Controlling Lights""; ""Controlling Appliances""; ""Controllers""; ""Gateways""; ""Lighting Control""; ""Hue""; ""Insteon""; ""Lifx""; ""Night Lights""…”

Tabla de Contenidos: “…Function ReturnsFunction Parameters; Project 7: HSB Color Mixer; Hooking It Up; Uploading the Source Code; Source Code Summary; Hardware Interrupts; attachInterrupt(); detachInterrupt(); Summary; CHAPTER 8 Arrays and Memory; Project 8: Decision Machine; Hooking It Up; Uploading the Source Code; Source Code Summary; Inclusions and Declarations; setup() and loop(); Functions; Arrays; Declaring Arrays; Using Arrays; Arrays of Values; Array Limits and sizeof(); Assigning Array Values; Character Arrays; Multidimensional Arrays; Arduino Memory; Checking Free RAM; Using Program Memory; Using EEPROM…”

Tabla de Contenidos: “…When in Doubt: Product DatasheetsDevice Packaging; Through-Hole DIPs; Surface-Mount Devices (SMDs); Extra Pins; Pin Descriptions; Power Pins; Digital and Analog Power Supplies; Analog Reference (AREF); RESET; XTAL1 and XTAL2; General-Purpose Input/Output (I/O) Ports; Alternate Pin Functions; AVR Core; Clock Sources; Address Spaces; Program Memory; Data Memory; Registers; Input/Output Registers; EEPROM; Configuration Fuses; Instruction Set; Machine Language Instructions; Internal Peripherals; General Purpose Input/Output (I/O); External Interrupts; Timer/Counters; Timer/Counter 0…”

Tabla de Contenidos: “…Reviewing the Sliced File and Printing; MatterControl's Capabilities; Using an SD Card; The MatterControl Touch Tablet; A Note about 3D Print Durations; Summary; Chapter 3: Downloading and Configuring MatterControl; Getting Started Using MatterControl; MatterControl Home Screen; OPTIONS Menus; Hardware Settings; Automatic Print Leveling; EEPROM Settings; Gcode Terminal; Cloud Settings; Sec9; Cloud Monitoring; Notification Settings; Application Settings; Update Notification Feed; Language Options; Slice Engine; Change Display Mode…”

Tabla de Contenidos: “…Decodificador de Texto; Descripción General; ST24LC21. Memoria EEPROM; Descripción General; TLC7733. Control de Tensión de Reset y Control de Baja Potencia; Descripción General; 74LVC257A. …”

Tabla de Contenidos: “…Compare ModeCapture Mode; 3.4 PIC16 C UART Serial Link; 3.5 PIC16 C SPI Serial Bus; 3.6 PIC16 C I[sup(2)]C Serial Bus; 3.7 PIC16 C Parallel and Serial Interfaces; Parallel Slave Port; Comparison of Communication Links; 3.8 PIC16 C EEPROM Interface; 3.9 PIC16 C Analog Output; Assessment 3; Assignments 3; Part 4 C Mechatronics Applications; 4.1 PICDEM Mechatronics Board Overview; PICDEM Hardware; Motor Drives; Test Program; Debugging; 4.2 PICDEM Liquid Crystal Display; LCD Connections; LCD Test Program; BCD Count Program; 4.3 PICDEM DC Motor Test Programs; Basic Control; Rev Counter…”

Tabla de Contenidos: “…Unser erstes Programm -- Programmieren in einer Arduino-Umgebung -- setup() -- Konzept EEPROM -- Konzept TIMER/Ticker -- loop() -- Vom Programm zum Board -- Der CAN-Bus -- Der Blick aufs Ganze -- Der Basisdecoder -- ESP-NOW als Alternative zum WLAN -- Der Decoder startet eine Wifi-Session im AP-Mode mit der eigenen MAC-­Adresse und dem Präfix »CNgrSLV« -- Der Decoder initialisiert sein ESP-NOW-System -- Den Master hinzufügen -- Nach Erhalt einer Quittung sind die Decoder empfangsbereit -- PING -- SWITCH_ACC -- BlinkAlive -- Die Decoder senden ihre PING-Antwort -- Die Decoder senden Konfigurationsdaten -- CONFIG_STATUS -- SYS_CMD/SYS_STAT -- Zusammenfassung -- Der Weichendecoder -- Festlegen der Weichenadressen -- Die Empfangsroutine -- Das Stellen der Servos -- Die Ausladung -- Zusammenfassung -- Der Formsignaldecoder -- Der LED-Signaldecoder -- Der Lichtdecoder -- Der Gleisbesetztmelder -- Die CANguru-Bridge -- Die CANguru-Bridge registriert Wifi-Sender mit dem Präfix »CNgrSLV« als eigene Clients -- Eine Quittung an die Clients geben -- Vom CANguru-Server den Frame 0x88 empfangen und mit 0x89 antworten -- Die Kommunikation der CANguru-Bridge -- Die CANguru-Bridge meldet sich über Telnet im Ausgabefenster des CANguru-Servers -- Die CANguru-Bridge empfängt die Datei »lokomotive.cs2« vom CANguru-Server -- Die CANguru-Bridge startet die Gleisbox -- Die CANguru-Bridge sendet einen PING an die Decoder -- Der CANguru-Server verfolgt die Übertragung der Konfigurationsdaten -- Wenn alle Decoder sich gemeldet haben, kommt die Meldung »Start WDP« -- Zusammenfassung -- Der CANguru-Server -- Der CANguru-Server sendet einen CAN-Frame mit Cmd 0x88 -- Der CANguru-Server trägt die IP-Adresse der CANguru-Bridge in das Feld oben links ein -- Der CANguru-Server empfängt die PING-Antworten der Decoder -- Der CANguru-Server baut eine Liste der Decoder auf…”

Tabla de Contenidos: “…-- The electrical lines -- I2C ports on the SAMA5D3 Xplained -- I2C ports on the Wandboard -- The I2C bus in Linux -- The I2C tools -- Getting access to I2C devices -- EEPROM, ADC and IO Expander -- EEPROM -- ADC -- IO Expander -- The temperature/humidity and pressure sensors -- Serial port -- The Raw I2C Bus -- Writing data in C -- Reading data in Python -- Summary -- Chapter 10: Serial Peripheral Interface - SPI -- What is the Serial Peripheral Interface bus? …”

Tabla de Contenidos: “…7.3.1 Interfaz Inter-Circuitos (I2C)7.3.1.1 I2C en C; Capítulo 8; 8.1 Introducción; 8.2 Organización de la memoria; 8.2.1 Arquitectura HARDVARD; 8.2.2 Memoria de Programa; 8.2.3 Contador de Programa; 8.2.4 Memoria de Configuración; 8.2.5 Pila; 8.2.6 Memoria de Datos; 8.2.7 Memoria EEPROM; 8.2.8 Modos de Direccionamiento; 8.2.9 Interrupciones; 8.2.9.1 Registros de salvaguarda; 8.2.10 Registro W; 8.2.11 Oscilador; 8.2.12 Unidades Funcionales; 8.2.12.1 Puertos de entrada/salida; 8.2.12.2 Temporizadores; 8.2.12.3 Convertidor Analógico-Digital; 8.2.12.4 Canal de Comunicación Serie (EUSART)…”

Tabla de Contenidos: “….) -- 17.3 EJEMPLO DE EMPLEO DE PANTALLAS OLED -- 18 PROGRAMACIÓN I2C -- 18.1 EJEMPLO DE EMPLEO DE UNA EEPROM I2C -- 19 PROGRAMACIÓN SPI -- 19.1 EJEMPLO DE PROGRAMACIÓN SPI DE UN (...) -- 20 PROGRAMACIÓN USB…”

Tabla de Contenidos: “…Using LEDs, LCDs and GLCDs in Microcontroller Projects; Contents; Preface; Acknowledgements; 1 Introduction to Microcontrollers and Display Systems; 1.1 Microcontrollers and Microprocessors; 1.2 Evolution of the Microcontroller; 1.3 Parts of a Microcontroller; 1.3.1 Address; 1.3.2 ALU; 1.3.3 Analogue Comparator; 1.3.4 Analogue-to-Digital Converter; 1.3.5 Brown-out Detector; 1.3.6 Bus; 1.3.7 CAN; 1.3.8 CISC; 1.3.9 Clock; 1.3.10 CPU; 1.3.11 EEPROM; 1.3.12 EPROM; 1.3.13 Ethernet; 1.3.14 Flash Memory; 1.3.15 Harvard Architecture; 1.3.16 Idle Mode; 1.3.17 Interrupts; 1.3.18 LCD Drivers…”

Tabla de Contenidos: “…7.2 7-Segment-Anzeigen -- 7.2.1 Port Expander über den I2C-Bus -- 7.3 LC-Display (LCD) -- 7.3.1 Paralleles LC-Display -- 7.3.2 Serielle LC-Displays -- 7.4 LC-Display Nokia 3310/5110 -- 7.5 OLED-Display -- 7.6 LED-Matrix -- 7.7 Projekt Geschwindigkeitsmesser fürs Fahrrad -- 7.8 Projekt Schrittzähler -- Kapitel 8: Datenverarbeitung -- 8.1 Daten speichern -- 8.1.1 Daten im Microcontroller speichern -- 8.1.2 Daten in externem EEPROM ablegen -- 8.1.3 Daten auf SD-Karte speichern -- 8.2 Daten ins Internet senden -- 8.3 Projekt: Programmierbarer Signalgeber -- 8.4 Sinusgenerator -- 8.5 Projekt Sollwerteingabe mit Drehgeber -- 8.5.1 Projekt-Erweiterung - Ausgabe als Analogwert -- Kapitel 9: Erweiterungen -- 9.1 Bibliotheken -- 9.1.1 Ethernet-Bibliothek -- 9.1.2 Wire-Bibliothek -- 9.1.3 SoftwareSerial -- 9.1.4 TinyGPS-Bibliothek -- 9.1.5 PString-Bibliothek -- 9.1.6 TextFinder-Bibliothek -- 9.1.7 JeeLib (nur Arduino UNO R3) -- 9.1.8 Stepper-Bibliothek -- 9.1.9 Wii Nunchuk -- 9.2 Hardware-Erweiterungen (Shields) -- 9.2.1 Protoshield -- 9.2.2 Protonly-Protoshield -- 9.2.3 Floweronly-Protoshield -- 9.2.4 Ethernet Shield -- 9.2.5 Datalogger und GPS Shield -- 9.2.6 Adafruit Motor Shield -- 9.2.7 DFRobot Motor Shield -- 9.2.8 Wave Shield -- 9.2.9 SD Card Shield -- 9.2.10 Lithium Backpack -- 9.2.11 ITEAD Power Shield -- 9.2.12 RFM12B Shield -- 9.2.13 Schraubklemmen-Shield -- 9.3 Hardware-Adapter -- 9.3.1 RFM12B-Breakout-Board -- 9.3.2 Wii-Nunchuk-Adapter -- Kapitel 10: Arduino im Einsatz -- 10.1 Verbindung zum Internet -- 10.1.1 Kabelgebundene Netzwerkverbindung -- 10.1.2 Arduino als Webserver -- 10.1.3 Der Arduino als Webclient -- 10.2 Verbindung zum Internet -- 10.2.1 Wifi mit UNO R4 WIFI (nur Arduino UNO R4 WIFI) -- 10.2.2 Wifi-Anwendungen mit UNO R4 WIFI -- 10.3 ESP-Module und Arduino -- 10.3.1 Integration in Arduino -- 10.3.2 ESP8266 -- 10.3.3 ESP8266-ESP12E…”

Tabla de Contenidos: “…4.1.5 Biological Nanowires -- 4.2 Properties of Nanowires -- 4.2.1 Electrical Properties of Nanowire -- 4.2.2 Mechanical Properties -- 4.2.3 Optical Properties of Nanowire -- 4.2.4 Nonlinear Optical Properties -- 4.2.5 Photovoltaic Properties -- 4.3 Nanowire-FET -- 4.4 Proposed Work (GaAs Nanowire-FET) -- 4.5 Conclusion -- References -- Chapter 5 Graphene Nanoribbon for Future VLSI Applications: A Review -- 5.1 Introduction -- 5.1.1 Significance of Nano-Scale Reign -- 5.1.2 Importance of Repeaters -- 5.1.3 Interconnect Models -- 5.1.4 Lumped Model -- 5.1.5 Distributed Model -- 5.1.6 Aluminum and Copper as Interconnects -- 5.1.7 Graphene Nanoribbon as Interconnects -- 5.1.8 Classification of GNRs -- 5.1.9 Fundamental Physics -- 5.1.10 According to Structure and Conductivity -- 5.1.11 GNR Field Effect Transistor (GNRFET) -- 5.1.12 Model Development of GNRFET -- 5.1.13 Pros and Cons of GNRFET -- 5.2 Future Applications of Graphene and Graphene-Based FETs -- References -- Chapter 6 Ferroelectric Random Access Memory (FeRAM) -- 6.1 Introduction -- 6.1.1 Basic Characteristics of Ferroelectric Capacitors -- 6.1.2 FRAM Fabrication Process -- 6.2 Structure of Ferroelectric Memory Cells in Capacitor-Type FRAM Devices -- 6.2.1 A Capacitor-Type FRAM with a Memory Cell Resembling DRAM -- 6.3 Write/Read Operations in the FRAM Using a Capacitor- Type Memory Cell that Resembles a DRAM -- 6.4 Other Capacitor-Type FRAM -- 6.5 FRAM of FET Type -- 6.6 Memory Utilizing a Ferroelectric Tunnel Junction -- 6.6.1 Previous Ferroelectric Memory Designs -- 6.7 Cross Point Matrix Array -- 6.8 Ferroelectric Shadow RAMs -- 6.9 2T2C Ferroelectric RAM Architecture -- 6.9.1 Evaluation of FRAM Devices' Reliability -- 6.9.2 Comparative Analysis of FeRAM to Other Memory Technologies -- 6.10 FeRAM vs. EEPROM -- 6.11 FeRAM vs. Static RAM -- 6.12 FeRAM vs. …”

“…Throughout the focus is on memory technologies which are complementary metal oxide semiconductor (CMOS) compatible, including embedded floating gate and charge trapping EEPROM/Flash along with FeRAMS, FeFETs, MRAMs and ReRAMs. …”

“…Get the right Arduino hardware and accessories for your needs Download the Arduino IDE, install it, and link it to your Arduino Quickly create, compile, upload, and run your first Arduino program Master C syntax, decision control, strings, data structures, and functions Use pointers to work with memory—and avoid common mistakes Store data on your Arduino’s EEPROM or an external SD card Use existing hardware libraries, or create your own Send output and read input from analog devices or digital interfaces Create and handle interrupts in software and hardware Communicate with devices via the SPI interface and I2C protocol Work with analog and digital sensors Write Arduino C programs that control motors Connect an LCD to your Arduino, and code the output Install an Ethernet shield, configure an Ethernet connection, and write networking programs Create prototyping environments, use prototyping shields, and interface electronics to your Arduino…”

“…You'll learn how to interface EPROM and EEPROM/FLASH memory as you explore the contents of that old video game or BIOS EPROM. …”