When a manufacturer offers a product for sale, the design engineers expect to have access to documentation that provides sufficient information to determine whether the product will perform as needed for the design under consideration. This is a fundamental requirement for electronic component parts and assemblies.
For components that are intended for use in assemblies, the manufacturer will not only furnish a datasheet covering the essential parameters of the part, but may also include an "Application Note" directly within the datasheet. This is usually in the form of a practical clarification of some aspect of the component, coupled with small block diagrams or schematics.
However, for more sophisticated parts, the Application Notes may exist as separate and more comprehensive documents. For a typical semiconductor datasheet, Texas Instruments Inc. (NYSE: TXN) has published a paper titled "How to Read Datasheets" by C.J. Ganier. The paper is fairly comprehensive; if you would like to become more familiar with datasheet terminology, this is an excellent introduction. Here is the intro of the Abstract:
For every electronic component or series of components, the manufacturer or designer produces a datasheet. In its early stages, a datasheet might be the specifications the designer works from; but, by the time the device is released, the datasheet is the essential piece of information that describes exactly what the component does. Everything from the smallest resistor to the most elaborate processor needs a datasheet.
Datasheets focus on electrical properties and the pin functions of the device; usually the inner workings of the device are not discussed. This is partly to make industrial espionage more difficult, and also because the user should not need to know the internal workings of the device. In practice, if you find that you need to know how a particular product works internally, you can often call the manufacturer and find what you need to know.
For most documentation, the following is covered in great detail:
Manufacturer's part numbers and associated options specific to unique characteristic variations of the part. These are usually found in a section labeled "Ordering Information." The main part number is usually at the top of the first page in a large, bold text.
The part description
A picture or line drawing of the part
The introductory general feature information
The package or form with dimensions
Pin-out diagrams
Tables for function and operating characteristics (usually specified as "Min," "Typ," or "Max"). Values, including, but not limited to:
Temperature
Voltage
Power
Power dissipation
Current
Impedance
Frequency
Timing
Value
Tolerance
Package -- form factor options with part number ordering information
Package thermal characteristics
Gain (for transistors)
Switching speed
Humidity or other Environmental limits
Additional drawings showing footprints, land patterns, or hole cutout specifications
Materials used to make the part if required by law
Charts showing various performance characteristics on a two-axis plot format
Component documentation should be quickly accessible via a part management system that is either 1) based upon a software database application that links "attachments" to part numbers; and/or 2) a hard-copy set of files storing all relevant documentation associated with the component or assembly part number. Refer to the core-disciplines tab at www.componentsengineering.com/core-discplines for more detailed information on this and related engineering subjects.
It is of the utmost importance to refer to the manufacturer's datasheets when qualifying a part to determine if the part performs as stated. Having the datasheet will also help with designing the qualifying test procedure unique to the component or component family type. Recently, Silicon Expert released a Web-based search engine that has datasheet information on more than 180 million parts. This engine can be found at www.datasheets.com or at other various (hosting) Websites, including www.ebnonline.com and www.componentsengineering.com. Datasheets.com also has inventory counts and costs at the various participating distributors. It is an excellent source for part availability searches in general.
Purchasing must also have access to the component data information but may not require the full set of datasheets. This is why the component engineer creates a Purchasing Specification Document (PSD) or a Specification Control Drawing/Document (SCD). This is an abbreviated form of the full specification citing the critical parameters of the part and usually incorporating a drawing of the part with dimensions, if applicable.
Many times, a vendor will take advantage of a purchasing agent's emergency part purchase requirement and suggest an alternate part that is not a true parametric substitute. The purchasing agent is bound to the PSD and is not allowed to purchase a substitute part that is not on the PSD or SCD. The purchasing agent may send non-proprietary PSDs to a vendor to help the vendor better match the original component, but the component can only be purchased after it has been added to the Part Master's approved vendors list by the component engineer or when a sustaining or design engineer has signed off on a temporary manufacturing deviation, thereby allowing the use of the substitute part only until the original manufacturer’s part number can be sourced.
This is the best way to avoid production problems due to underperforming or non-performing part substitutions. PSDs and SCDs must also be under revision control. A PSD form template is downloadable here.
Having all the datasheets available either in hard copy or in PDF soft copy with links is the best practice for rapid retrieval of critical part information. These datasheet files should be part of the overall project file created for the product during the R&D phase.
-hm and All,
http://www.componentsengineering.com/wp-content/uploads/pdfs/Sample-Request-Form-1.pdf
This is one of two forms I use to save myself a lot of work in selecting or qualifying new or alternate source parts. It takes into consideration the advice of -hm and then some more key items. I give the factory or distributor rep this URL and ask them to complete the form and submit it with the sample parts they are offering. Together with the "Component Information Request" form, I am asking the person selling me the parts to do all the research before I can accept their samples. Questions like, " How long have the parts been in production?" and "What are the reliability numbers?" etc., help me qualify both the part and supplier quickly. More importantly, it helps me disqualify the part and not have to spend unnecessary time in house with qualification procedures. The Reps fill out the forms and often discover the parts are not good alternates as Operating Characteristics may be different or unacceptable. Just give your supplier the URL every time they want to introduce a part and you will have a much easier time with sample part management and allowing or disallowing a supplier as well.
It is also important to read about parts information other then electrical and mechanical characteristics. RoHS compliance, country of origin (free from political troubles), long term stability of vendor and their financial health is also quite relevant in selecting vendor and parts.
It is nice to work with parts from reputed semiconductor vendors. However, when one is to employ specialized semiconductor parts from small manufacturer, data is very limited. It is very difficult to enhance the circuit function in different topology. Designer task becomes very daunting.
So I zoomed in on your symbol and it looks like epsilon (small) or Sigma (large). I think the omicron is just the degree symbol common accross all usage. I suspect that the symbol was either a typo, or represented a quantity from an earlier calculation on the datasheet carried forward. It could be that it represents a summation of vectors or a non-conventional use for phase angle. I would really like to see that datasheet.
It looks like Greek to me. Epsilon and omicron or omega. I have never seen this meaning 45 degrees. Can you scan the datasheet and send it to my email at douglas@componentsengineering.com? Anyone else ever see this? Epsilon usually means "Sum" in formulas. Maybe it is borrowed from another discipline like the building or construction business.
There are some great datasheet archive websites that store every revision of a datasheet and most application notes that refers to the part. It's useful to an engineer to have the complete data set to pick from.
Every datasheet store in the world has huge gaps in their data. Especially PDF datasheets pre 2000. In the 90s datasheets and application notes would disappear from manufacturer websites and be gone forever.
Machine-to-machine technology is growing so rapidly that one report says there could be 10 billion connected devices by 2016. That's a big market opportunity.
RFID makes it possible not only to increase the quantity and types of products streaming through the supply chain, but also to build higher-level products and services.
EBN Dialogue enables and encourages you to participate in live chats with notable leaders and luminaries. Not only editors and journalists, but the entire EBN community is able to comment and ask questions. Listed below are upcoming and archived chats.
Archived Dialogues
Thailand Stages a Comeback Join EBN contributor Jennifer Baljko on Thursday August 23, 2012, at 11:00 a.m. EST for a live chat on how electronic manufacturers in Thailand have shored up their supply chain to reduce the impact of future natural disasters.
Euro-Crisis: What It Means for High-Tech Firms Join EBN Editor in Chief Bolaji Ojo and Contributing Editor Jennifer Baljko on Thursday, July 12, at 10:00 a.m. EDT for a Live Chat on high-tech and Europe's economic difficulties.
Microsoft Surface: Potential Winners & Losers What are the implications for the electronics industry supply chain of Microsoft Corp.'s decision to launch its own tablet PC? Join industry veteran and EE Times' systems and OEM expert Rick Merritt on Tuesday, July 3, at 12:00 pm EDT for a Live Chat on this subject.
Join EBN contributor Jennifer Baljko on Thursday August 23, 2012, at 11:00 a.m. EST for a live chat on how electronic manufacturers in Thailand have shored up their supply chain to reduce the impact of future natural disasters.
Peter Drucker famously said "Trying to predict the future is like trying to drive down a country road at night with no lights while looking out the back window." Yet in the razor's-edge world of electronics—with a lean supply chain and just-in-time demands—the need to know the future is vital.
While no one really can accurately predict the future, we can take guidance from another Drucker saying which is the best way to predict the future is to create it.
You've heard the saying "the No. 1 supply chain risk is your people." That hasn't always been the case. But today's complex global supply chain requires a new type of multitalented employee. It's one who understands, finance, marketing, economics, is savvy with technology, graceful with relationships and can think analytically.
Where are these people? Are universities properly preparing the next generation supply chain professionals? How do train your existing workforce for these new, demanding positions?
Brian Fuller, editor-in-chief of EBN, will lead a 60-minute Avnet Velocity panel discussion that will ask and answer these and other questions swirling around today's supply-chain talent challenges.
To save this item to your list of favorite EBN content so you can find it later in your Profile page, click the "Save It" button next to the item.
If you found this interesting or useful, please use the links to the services below to share it with other readers. You will need a free account with each service to share an item via that service.
Tweet This