I’m reluctant to pay $150 for a pair of “performance” output coils for my bike when I know I can get Accel automotive output coils at AutoZone for $30 a pop. I know they’re large, but size isn’t a concern. Is there any specific reason mechanically or electrically that this is a bad idea?

What’s a good reference book for automotive repair, maintenance, and tuning. I’m trying to learn all I can about cars and need a good place to start. I’m hoping to get to the point where I can do mods and performance tuning one day (not ****** rice cans, I mean American V8 classics and modern muscle cars).

Automotive training used to be a more common part of our society. Shop class was a commonly offered elective in high schools nationwide, ensuring that most boys knew their way around a car’s engine bay. Additionally, cars relied more on mechanical principles, rather than computerized systems. As a result, when a car broke down, the owner was much more likely to know how to fix it themselves, or at least have a friend or a family member who could fix it for them.

The situation has changed dramatically over the years. Today’s cars are much more complex, and their owners are much less likely to have had any automotive training. As a result, dealerships and garages are repairing a higher percentage of cars than ever before, and mechanics’ rates have risen in accordance with the increased necessity of their services.

Those who dislike the situation have another option. With a little automotive training, most people can perform more of the routine maintenance on their cars, reducing the expenses associated with car maintenance and allowing them the satisfaction of a job well done.

An oil change is an example of routine maintenance that frequently costs car owners far more than they need to spend. An oil change is a fairly simple procedure in most cars, requiring only enough automotive training for the individual to know the location of the oil filter and drain plug. A basic car care class should teach car owners how to locate major components under the hood and perform simple maintenance tasks, as well as imparting valuable tips for beginning do-it-yourselfers. For example, a good introductory class should warn students to beware of screwing a bolt or screw in crooked, known as crossing the threads.

A basic tune up is another routine maintenance task that do-it-yourselfers should be able to handle with a little automotive training. A basic tune up usually consists of changing the air filter, spark plugs, plug wires, distributor cap and rotor, and positive crankcase valve (PCV). Depending on the car and the mileage recommendations on the components, a basic tune up can also include replacing the fuel filter and/or the oxygen sensor. Rubber parts, such as drive belts and radiator hoses, may also be checked and replaced during a tune up. On most cars, these parts are easily accessed and require only a basic understanding of automotive functions.

A do-it-yourselfer who has had basic automotive training can also replace his or her own brakes. Changing the brake pads on a car is typically a dirty but simple job, requiring only a basic understanding of the braking components on a car. Additionally, there are numerous routine maintenance and repair jobs that an intermediate level amateur mechanic can usually handle on his or her own, such as replacing a battery, alternator, starter, timing belt, and many other components.

Of course, a significant advantage of having automotive training is that dealerships and garages cannot take advantage of you by recommending maintenance that may not actually need to be done. A basic understanding of auto mechanics will enable you to intelligently discuss any problems with your mechanic, understand what he or she is talking about, and recognize when his or her recommendations are exaggerated or downright unnecessary.

Obviously, knowing the basics of how a car operates can be extremely beneficial, saving you money in more ways than one. Beginning automotive training classes are usually offered at your local auto tech school or community college. Whether you intend to venture a few repairs on your own, or you simply want to be able to hold your own with your mechanic, taking a car care class ensures that you will not be a victim of your own ignorance.

Advanced Technology Solutions for Automotive & Semi Conductor Industries

An ever-increasing range of leading-edge technologies emerging into the manufacturing, more so in the automotive & semi-conductor sectors, make them two of the most exciting and dynamic manufacturing sectors in the world.

Automotive & Semi-conductor industries are facing an extremely challenging business environment today with increase in product heterogeneousness, higher dependence on outsourcing, and a growing need to collaborate with an unending list of business partners. Moreover, with the automotive electronics market exploding and semiconductor consumption booming worldwide, the tremendous opportunity for semiconductor companies brings with it the increasing pressure to keep pace with the shortening development cycles and the need for newer and more innovative products. However not all the products that hit the market are successful since the consumer today is extremely particular about price and performance, leaving semiconductor companies to grapple with the triple challenges of increasing complexity, shorter timelines and increasing risk. In fact the need to excel by improving quality, creating product differentiation while meeting safety and other regulations has kept both the industries on their toes.

This kind of situation has given impetus to Advanced Technology Solutions, solutions that enable the automotive as well as semi-conductor industries to attain performance advancements and improved efficiency. Partnering with an organization offering industry specific advanced technology solutions in the focused areas of Automotive Electronics, Engineering Design, Product Engineering, Auto Infotainment & Telematics, Instrument clusters, Industrial automation, Powertrain, Chip design, Embedded software, Analog mixed signal design, Electronic design, Physical design, Semiconductor design outsourcing, ASIC/SoC development, Vlsi design, FPGA design solutions, and support services such as Verification & Validation, Offshore testing and Automotive embedded software, is a viable option that can leverage the technology expertise in automotive electronics & semi-conductor solutions. It further helps in accelerating product development cycles and push the envelope of innovation.

Utilizing these Advanced Technology Solutions, the automotive & semi-conductor industries can collaborate with a vast array of business partners and suppliers working in tandem to design and manufacture vehicles and focus on providing innovative silicon chip design and embedded software support.

It doesn’t seem too long ago that the electrical system in a vehicle was mostly concerned with lights, starter motors, radios and windshield wipers. Those days are long gone. The automotive industry is currently realizing a dramatic increase of electronic equipment for onboard vehicle control. In modern cars, a variety of electronic control units (ECU) delivers sophisticated real-time control functionality.

In the automotive industry, there is little doubt that electronics growth will continue. To remain competitive, it is crucial to seamlessly integrate the new technology. Whether it’s an entertainment system, keyless entry, a back-up camera or touch screen navigation, the role of the automotive manufacturer is increasingly becoming that of a system integrator working closely with its suppliers.

There is a long tradition in the industry of working with suppliers, and a number of suppliers that exist deliver similar systems to vehicle manufacturers. Automotive suppliers are more than happy to fill the needs of manufacturers, and the ever increasing importance of electronics in automobiles brings with it a growing challenge and need for low-cost, reliable electronic systems. These systems are not isolated and must communicate with each other.

Historically, automotive electronics have relied on proprietary, dedicated wire communication schemes (at least for many sensor systems) and directly wired power outputs. This has led to excessive wiring, and wiring consumes space, adds weight and expense, and can be difficult to maintain.

Fortunately, advances in vehicle-networking standards are addressing these issues with the wide adoption of Controller Area Network (CAN) and Local Interconnect Network (LIN) architecture. These network standards are providing a balance between performance and cost optimization across automotive systems. CAN provides a high-speed network for chassis, powertrain and body-backbone communications, while LIN answers the need for a simple network for sensor and actuator subsystems that reduces cost and improves robustness through standardization. Together, the vehicle networking standards and advanced mixed-signal processes provide an opportunity for automotive manufacturers to introduce affordable new electronic systems as well as reduce costs. They also improve maintenance and reliability while providing advanced convenience and safety features, like collision avoidance.

The widespread adoption of CAN and LIN standards is an important development for automotive electronics and becomes much more significant in conjunction with recent advances in mixed-signal semiconductor processes.

Adopting standardized vehicle-networking architectures and using more highly integrated mixed-signal ICs bring several advantages at the system level. The first is an improvement in a system’s robustness and diagnostics. By adopting standardized networks for two-way communication, diagnostic and failure information can be obtained when there are issues with the system.

The second is a reduction in wiring requirements. Using standardized vehicle-networking architectures, it is possible to build a feature- and diagnostic-rich system that requires only three wires. Reduced wiring requirements have less cost, less weight, will be easier to install at the factory, and will help reduce the potential for failure.

Integration also leads to other advantages and savings. Printed Circuit Boards (PCBs) and housings can be smaller, allowing for improved and more flexible placement in the vehicle, with less concern about where and how to run the wires. Through the use of fewer components, there are fewer items to keep in inventory, qualify and monitor. Some of these factors also lead to a reduction in weight and space consumption, factors that are always important in vehicle design.

This advance is another step in increasing the intelligence and capabilities of automotive systems. We’re already witnessing this increased intelligence and capability with complex navigation systems, Internet access, passenger entertainment, ABS brakes, engine management systems and advanced stability control. The next generation of mixed-signal automotive integrated circuits (ICs) will integrate even more performance and processing power. It will provide programmable features and added flexibility that will be used to address the automotive electronic system needs of tomorrow. As these systems become more advanced, the possibilities are limited only by the applications that vehicle designers can imagine and that the end customer is willing to purchase.

What’s a good reference book for automotive repair, maintenance, and tuning. I’m trying to learn all I can about cars and need a good place to start. I’m hoping to get to the point where I can do mods and performance tuning one day (not ****** rice cans, I mean American V8 classics and modern muscle cars).

For the legendary Lamborghini sports car stable of fantastic ultra high performance and styled vehicles it all started with ordinary Fiat automobiles and tractors.

Mr. Lamborghini – fully named – Mr. Ferruccio Lamborghini got his start with Fiats and then went on to a large successful manufacturing concern that grew from a small manufacturing shop into a major producer of tractors. However at a certain point in every person’s life they search out to complete what their real passion is. In the case of Lamborghini was finely styled and crafted motor cars. At 60 years of age, an established manufacturer of agricultural tractors – Mr. Lamborghini – decided that he could a better job of building a high end, beautifully styled, performance racing automobiles than either of the two dominant Italian auto firms of that auto industry sector – Ferrari and Maserati.

The first product out of the door had a chassis that was multi-tubular; the engine was front mounted sporting a 3.5 liter 12 cylinder V-12 engine. The V-12 engine itself was fitted with six Weber carburetors and ran four overhead camshafts. It all clocked at 360 ultra smooth horsepower with the transmission drive being through five speed stick shift. Suspension involved a coil and wishbone independent suspension set up. In one word it was wow – both in terms of performance of the hop as well as the automotive styling.

Although the styling of those early Lamborghini models may be considered standard Italian sports car design – designs which have worked their way into the so called standard “sport scar designs “and “sport scar flair”, at the time it was new and innovative and for the most part if was twenty five years ahead of anything produced in the good old U.S.A. . The one American sports car which might be considered an exception to that point was the Chevrolet Corvette. For years to come nothing else really matched or was similar to the clean aerodynamic lines and styling of the early Lamborghini classic autos.

Even then Lamborghini had such innovative products the establishment and reputation of the Lamborghini product line was no easy road to hoe. Although the first cars were produced in 1963 it was not for two years later – at the Turin Motor Show that the car began to attract solid interest and for the reputation of the car and its studio to grow and begin to become accepted for what it should be.

The first real product of record for Lamborghini was what was marketed as Miura T 400 model automobile. Its first year of manufacture was the 1966 model year. The basic layout and design of the Miura T 400 was a mid-engined coupe with a slightly larger version of the overhead cam engine – the classic V-12 laid out transversely behind the two seats of the car. The rear wheels were then driven by this engine through” spurs gears”. Interestingly the gear boxes and rear axles were Lamborghini products all by themselves -so they shared a lineage that was unique and not the same as any other of the competitor’s models.

What was performance of this little cat? The V-12 engine could pour out a total of 385 barrel horsepower. Top speed of this little coupe was over 180 miles per hour. It could more than carry its weight with the local Italian contenders – even the famed Ferraris.

If the was one complaint from drivers or riders it was of noise levels in the car’s cockpit. It can be said that this was the price to be paid for success or in this case speed and performance. If you cannot stand the heat don’t stay in the kitchen. Certainly the buyers of Lamborghini fine motor cars who bought the product and established the revered name for its performance and advanced styling and forgo this small shortcoming or foible as the car as an assumed fact – even a luxury.

The next model in the Lamborghini stable was introduced approximately two years later. The entire life of the production run of the popular Miura model was nine years – with two cars being produced a week ( a production figure of only 100 or so cars a year). The name of this vehicle was the Espada. For the new Lamborghini model, the Espada, Lamborghini went back to a more standard front engine layout. Perhaps this was in response to concerns over noise levels in the cockpit of the Miura and the need to produce a more “standard” or “civilized “vehicle product. No one really knows what went on in the mind of the genius Ferruccio Lamborghini. However what was retained for sure were the Lamborghini basics – the four liter V-12 massive highly tuned engine with whizzy overhead cams and multiple choke carburetors all putting out massive automotive performance and handling.

In the end it can be said that the Lamborghini automotive and automotive styling and performance legends are more than unique and reek of power, thrust and acceleration.

Hello everyone out there in the automotive world. Im 16, dad gave me his prized possession of a 1967 Pontiac GTO. Im so stoked on it and have been wanting to have a project car for a while. The body work and interior is all being done by body shops and other professionals like that. My problem is working with my engine. Its beautiful and sounds like a BEAST, but i want to learn more about it, and frankly its a lot. i get the main concept of how motors run and what a carb. is and fuel injectors, but like i want to sup this babby up!! put some performance parts on her. people say the easiest way to learn is by taking your car apart and putting it back to gether.! Bull Shi+. You dont know the names and what they do! so people i want a real answer. something that will help me.
(maybe study it?? take class at community college?)
i dono you tell me!
LOVE THE 4oo HP!