9. 8/16 bit Low Power MCU Selection Guide Manufacturer Part Number Farnell # Newark # Description TI MSP430FG477 nil 24R9824 16-bit, Ultra-Low-Power MCU with LCD and ADC TI MSP430F478 nil 73M3249 16-bit, Ultra-Low-Power MCU with LCD and ADC TI MSP430FG4618 1470488 22M1151 16-bit, Ultra-Low-Power MCU with LCD and ADC TI MSP430FG4619 1555279 94M8446 16-bit, Ultra-Low-Power MCU with LCD and ADC TI MSP430FG437 1471275 16-bit, Ultra-Low-Power MCU with LCD and ADC TI MSP430FG439 1555272 05J2133 16-bit, Ultra-Low-Power MCU with LCD and ADC TI MSP430FG4250 1503385 54M7241 16-bit, Ultra-Low-Power MCU with LCD and ADC TI MSP430FG4260 54M7246 16-bit, Ultra-Low-Power MCU with LCD and ADC Freescale MC9S08LL16 1748991 26R6794 Ultra-Low Power Segment LCD Microcontroller Freescale MC9S08LG16CLH 1718379 74P0410 8-bit LCD Microcontrollers Freescale MC9S08LL64 1780362 14R8911 Ultra-Low Power Segment LCD Microcontroller Freescale MC9S08LL8 40P5129 Ultra-Low Power Segment LCD Microcontroller Freescale MC9S08LG32CLF 1718380 74P0411 8-bit LCD Microcontrollers Microchip PIC16F727 1659768 07P9656 8-bit Extreme Low Power Microcontroller with nanoWatt XLP Technology Microchip PIC18LF14K50 1701040 07P9719 8-bit Extreme Low Power Microcontroller with nanoWatt XLP Technology Microchip PIC18F46K20 1664863 88K6053 8-bit Extreme Low Power Microcontroller with nanoWatt XLP Technology Microchip PIC24F16KA102 1707629 40M1461 16-bit Extreme Low Power Microcontroller with nanoWatt XLP Technology Atmel ATMEGA3290P 1704562 08R5494 8-bit picoPower Technology AVR Microcontroller Atmel ATMEGA169P 1675975 33P6478 8-bit picoPower Technology AVR Microcontroller
10. 32 bit Low Power MCU Selection Guide Manufacturer Part Number Farnell # Newark # Description TI AM1705 69R1052 ARM Microprocessor TI AM1707 64R0844 ARM Microprocessor TI AM1806 ARM Microprocessor TI AM1808 64R0845 ARM Microprocessor NXP LPC3130FET180 1718537 15R1841 Low-cost, low-power ARM926EJ-S MCUs with high-speed USB 2.0 OTG, SD/MMC, and NAND flash controller NXP LPC3131FET180 1718539 15R1842 Low-cost, low-power ARM926EJ-S MCUs with high-speed USB 2.0 OTG, SD/MMC, and NAND flash controller NXP LPC3180FEL320 1524648 70R5687 16/32-bit ARM microcontroller; hardware floating-point coprocessor, USB On-The-Go, and SDRAM memory Interface NXP LPC3220FET296 70R5689 16/32-bit ARM microcontrollers; hardware floating-point coprocessor, USB On-The-Go, and EMC memory Interface NXP LPC3230FET296 70R5691 16/32-bit ARM microcontrollers; hardware floating-point coprocessor, USB On-The-Go, and EMC memory Interface NXP LPC3240FET296 70R5693 16/32-bit ARM microcontrollers; hardware floating-point coprocessor, USB On-The-Go, and EMC memory interface NXP LPC3250FET296 70R5695 16/32-bit ARM microcontrollers; hardware floating-point coprocessor, USB On-The-Go, and EMC memory Interface
11. DSP Selection Guide Manufacturer Part Number Farnell # Newark # Description ADI ADSP-BF537BBCZ-5A 1317616 21M6774 Blackfin Embedded Multiprocessor ADI ADSP-BF537BBCZ-5AV 1642359 64M7483 Blackfin Embedded Multiprocessor ADI ADSP-BF547BBCZ-5A Nil 19P8218 Blackfin Embedded Processor ADI ADSP-BF547KBCZ-6A Nil 08R6641 Blackfin Embedded Processor ADI ADSP-BF548MBBCZ-5M Nil 08R6642 Blackfin Embedded Processor Freescale MSC8113 1692089 12N7683 Tri-Core Digital Signal Processor Freescale MSC8112 1692088 12N7680 Dual Core Digital Signal Processor TI TMS320C6421 Nil 72M4749 Fixed-Point Digital Signal Processor TI TMS320C6424 Nil 65M5952 Fixed-Point Digital Signal Processor TI TMS320C6472 Nil 72R6614 Fixed-Point Digital Signal Processor TI TMS320C6474 1791956 72R6619 Fixed-Point Digital Signal Processor
12. FPGA Selection Guide Manufacturer Part Number Farnell Newark Description ALTERA EP2C5 1453497 03P4313 Cyclone II FPGA Family ALTERA EP2C8 1453487 58M5903 Cyclone II FPGA Family ALTERA EP2C15 1549347 94M7222 Cyclone II FPGA Family ALTERA EP2C20 1453472 94M7225 Cyclone II FPGA Family ALTERA EP2C35 1453466 94M7232 Cyclone II FPGA Family ALTERA EP2C50 1635090 15P1541 Cyclone II FPGA Family ALTERA EP2C70 1635091 03P4318 Cyclone II FPGA Family
13. Power Management Selection Guide Manufacturer Part Number Farnell # Newark # Description ADI ADP2503 11R0638 600mA, 2.5MHz Synchronous Buck-Boost DC-DC Switching Regulator ADI ADP2504 63R9770 1A, 2.5MHz Synchronous Buck-Boost DC-DC Switching Regulator Linear LT3080 1556600 75M4716 Adjustable 1.1A Single Resistor Low Dropout Regulator Linear LT3574 1792368 63R6859 Isolated Flyback Converter IC Linear LTC3407 1432765 56M7598 Dual Synchronous, 600mA, 1.5MHz Step-Down DC/DC Regulator Linear LTC3411 1663708 56M7681 1.25A, 4MHz, Synchronous Step-Down DC/DC Converter Microchip MCP1701A 1605554 11N7985 LDO Regulator Microchip MCP1702 1627173 09P3987 LDO Regulator Microchip MCP1703 1627178 09P3988 LDO Regulator Microchip MCP1253-33X50 1332067 03H5060 DC-to-DC Converters Microchip MCP1252-33X50 1332064 59K0222 DC-to-DC Converters NS LM22670 1679653 08P5273 3A SIMPLE SWITCHER®, Step-Down Voltage Regulator NS LM22671 1679657 08P5277 500mA Simple switcher ®, Step-Down Voltage Regulator NS LM22672 1679659 19P7830 1000mA Simple switcher ®, Step-Down Voltage Regulator NS LM2594 1469190 41K3810 Simple switch Power Converter 150 KHz 0.5A Step-Down Voltage Regulator TI REG104GA-5 1207261 75C7549 Single Output LDO, 1.0A, Fixed (5.0V) TI REG1117-5 1212858 20M1510 Single Output LDO, 800mA, Fixed(5.0V) TI TPS63001 1652399 85K1711 96% Buck-Boost Converter with 1.7A Current Switches, 3.3V fixed Output voltage in TI TPS63002 1535677 85K1713 96% Buck-Boost Converter with 1.7A Current Switches, 5V fixed Output voltage in TI TPS63010 1647820 14N8521 High Efficient Single Inductor Buck-Boost Converter with 2-A Switches
14. Touch Screen Controller Selection Guide Manufacturer Part Number Farnell # Newark # Description ADI AD7843ARQZ 1226197 19M8858 4-Wire Resistive Touch Screen Controller w/ 2 Aux Inputs & 8-Bit SPI Interface. Uses Ext Reference ADI AD7843ARUZ 1699610 59K5648 4-Wire Resistive Touch Screen Controller w/ 2 Aux Inputs & 8-Bit SPI Interface. Uses Ext Reference ADI AD7873ACPZ 1464744 19M8859 4-Wire Resistive Touch Screen Controller w/ Temp Sensor, 2.5V Ref, and Aux & Battery Inputs ADI AD7877ACPZ-500RL7 1226200 19M8860 4-Wire Resistive Touch Screen Controller w/ Noise Reduction, DAC, Conversion Controls, & GPIO ADI AD7147ACPZ-1500RL7 1699633 19P8278 CapTouch® Programmable Controller for Single-Electrode Capacitance Sensors ADI AD7147ACPZ-500RL7 1699634 19P8279 CapTouch® Programmable Controller for Single-Electrode Capacitance Sensors ADI AD7148ACPZ-1500RL7 Nil 84M7803 Programmable Touch Controller for Single Electrode Capacitance Sensors Atmel AT42QT5320 Nil Nil QTwo™ 10-bit touchscreen Controller Atmel AT42QT4120 Nil Nil QField™ 10-bit touchscreen Sensor IC Atmel ATA42QT4160 Nil Nil Single-layer touchscreen controller Atmel mXT224 Nil Nil 224-node highly configurable touchscreen controller TI AD7843 Nil 35C1556 4-wire Touch Screen Controller TI AD7845 Nil 35C1560 5-wire Touch Screen Controller TI AD7846 1703450 35C1561 Touch Screen Controller
Welcome to the solution module on Handheld signal generator. This training module introduces basic working principle and its different components involved
An electronic test instrument that delivers a sinusoidal output at an accurately calibrated frequency that may be anywhere from the audio to the microwave range There are many different types of signal generators, with different purposes and applications (and at varying levels of expense) signal generators have been embedded hardware units
Signal generators can be divided into two types depending on their memory options and clocking characteristics. These two categories are function generators and arbitrary waveform generators (AWGs). Signal generators use the synchronization and memory core (SMC) architecture to provide a common interface between a device's onboard memory. The SMC also offers many advanced marker and trigger features for synchronization with other instruments
The AWG’s playback scheme can be thought of as “sampling in reverse.” It acquires a waveform by digitizing the analog signal’s voltage value at a succession of points in time, with the frequency of the sampling being determined by the user-selected clock rate. The resulting samples end up in a memory. The AWG starts with a waveform already in its memory. The waveform occupies a designated number of memory locations. With every clock cycle, the instrument outputs another waveform sample from the memory The AFG maintains a fixed system clock frequency. The 360 degrees of a waveform cycle are spread across the full number of waveform samples, and the DDS section automatically determines the phase increments based on the waveform length and the frequency selected by the user.
Signal Generators produce complex RF signals utilizing one of two primary up-conversion techniques: heterodyne or direct. The heterodyne approach employs digital up-conversion to create a digital intermediate frequency (IF) which is converted into the RF domain through the use of a single Digital to Analog Converter (DAC) and a single or multi-stage mixer. The direct conversion architecture is often found in modern Vector Signal Generators because of the simplicity and cost effectiveness of design. Two DACs are utilized to create analog I and Q signals which are then mixed with a local oscillator to product two signals that are 90 degrees out of phase. These translated baseband signals are then summed to produce the RF signal.
The complete signal generator block consist of sub systems like DSP processor, baseband block which contain onboard interpolation filters (FIR) that are configurable in either Low-Pass or High-Pass mode, RF up conversion, Power management block based on a computer architecture, leveraging display, interface, and power management functions from the high-volume PC market
The TMS320C6472 device is a Texas Instruments next-generation fixed-point digital signal processor (DSP) targeting high-performance computing applications, including high-end industrial, mission-critical, high-end image and video, communication, media gateways, and remote access servers. This device was designed with these applications in mind. A common key requirement of these applications is the availability of large on-chip memories to handle vast amounts of data during processing. With 768K-Byte of shared RAM and 608K-Byte local L2 RAM per C64x+ Megamodule, the TMS320C6472 device can eliminate the need for external memory, thereby reducing system power dissipation and system cost and optimizing board density.
This page gives 8/16 bit Low Power MCU Selection Guide for signal generator solution along with Premier Farnell order codes.
This page gives 32- bit Low Power MCU Selection Guide for signal generator solution along with Premier Farnell order codes.
This page gives DSP Selection Guide for signal generator solution along with Premier Farnell order codes.
This page gives FPGA Selection Guide for signal generator solution along with Premier Farnell order codes.
This page gives Power Management Selection Guide for signal generator solution along with Premier Farnell order codes.
This page gives Touch Screen Controller Selection Guide for signal generator solution along with Premier Farnell order codes.
This page gives Segment LCD Display Selection Guide for signal generator solution along with Premier Farnell order codes.
This page gives Reference Generator Selection Guide for signal generator solution along with Premier Farnell order codes.
This page gives Peripheral Solution Guide for signal generator solution along with Premier Farnell order codes.
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