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/PRNewswire/-Reportlinker.com announced that new market research reports are available in its catalog:
This global market analysis includes 146 pages, covering all aspects of the global linear resistor market. The linear resistor market includes thick film ruthenium chips, resistor networks, resistor arrays, integrated passive devices; wire wound resistors, nickel-chromium alloy metal film resistors, bulk metal foil resistors, carbon film resistors, and nitride Tantalum resistors, NiCr chip resistors and carbon composite resistors. The research contains all available market data related to advanced market research reports, including consumption by type and resistive elements; consumption by end market segment, market share by subcategory, 2011-2015 The forecasts, technical and economic analysis, including the change in resistance from ruthenium to nickel. Research on display technology by resistor type and structure, display market by type and structure; market by world region, market by end-use market; market share of chip, network and through-hole resistors; unit number of component subtypes Forecast of shipment volume, unit value shipment volume and average unit price. Including 17 different types of resistor categories and lead times for case sizes; trends in resistors in emerging markets. This research report also analyzed in detail the revenue changes of the world's top linear resistor suppliers in the 2011 fiscal year.
resistance:
Figure 1.1: Linear resistors and their respective subcategories: 2011
Analysis and conclusion:
Year-on-year growth rate of the world's top resistor manufacturers in fiscal 2011: million
Competitive environment: Top 79 suppliers of resistance type
Top supplier of linear resistors: fiscal year 2011
Vishay Intertechnology, Inc.
Vishay: Growth of resistor and inductor product categories in fiscal 2011
KOA Company
KOA: Resistor revenue growth in fiscal 2011
Panasonic Electronic Equipment
PED: Resistor revenue growth in fiscal 2011
Kunio
Yageo: Resistor revenue growth in fiscal 2011:
TTePLC (IRC / BITech / Welwyn):
TTePLC: Resistor revenue growth in fiscal 2011
Huaxin Technology
Walsin / Kamaya: Resistor revenue growth in FY2011
Roman co., ltd.
Rohm's 2011 fiscal year resistor revenue growth
Hokuriku electric co., ltd.
Hokuriku EC's 2011 fiscal year resistor revenue growth
Akabane Electronics Industry Co., Ltd.
Akabane-Estimated resistor revenue growth in FY2011
TA-I technology
TA-I 2011 fiscal year resistor revenue growth
The true nature of the competition: fiscal year 2011
The statistical interpretation of resistance in this report:
HTS Code 8533: Resistor category and definition:
Military specification resistors:
-MIL-R-39035
Resistance in a circuit: how a component becomes a commodity:
The importance of the physical size of the finished resistor
Figure 1.2: Technical and economic criteria related to resistance:
Linear resistor products and technology:
-Thick film chip resistors:
The high dependence on thick film technology caused some OEMs to question the supply chain in 2011:
Thin film resistors
Technical overview:
Market acceptance of nickel-chromium chips
Thin Film Chip Resistors: Estimated Market Size: 2011
Top 22 suppliers of thin film chip resistors in 2011
The world's top 40 thick film chip resistor market manufacturers and market leaders
-Thick film multi-chip resistor array:
Technical overview:
Thin film multi-chip arrays: 2011 world market sales and value:
Success history of chip array mass production; price failure
Top 18 thin-film multi-chip array suppliers in 2011
Traditional SIP, DIP and flat packaging
-Dual in-line package resistor network
-Single row package resistor network
Technical Note: 2011
Array encroachment:
Substrate and metal:
Changes in RC and Flatpack:
40 years of technology:
Resistor Network Market in FY2011
Top 34 traditional thick film resistor network suppliers in 2011
-Integrated passive device network
Thin film precision emerging markets:
Thin film metal and deposition:
Integrated passive device network market: 2011
Thin film network and integrated passive equipment supplier: 2011
-Wire wound resistors
Technical overview:
Configuration:
Winding:
Unique power handling aspects:
Wire type:
High-power customized market:
The competitive environment:
Market Value and Sales Volume of Wire Wound Resistors: 2011
-Nichrome metal film resistors
Nickel + chromium film resistors:
Precision resistors: current sensing
Ni-Cr alloy film market: 2011
Nichrome MELF market: 2011
Nichrome axial and radial lead market: 2011
Top nickel-chromium alloy thin film resistors (axial and radial leads): 2011 and market leader
-Bulk metal foil resistors
Unique nature of technology: modernity
Bulk metal foil resistor market estimate: 2011
The top 7 metal foil resistor suppliers and market leaders in 2011
-Tin oxide resistance
High voltage resistance> 500 Vdc
Tin oxide resistor market: 2011
Tin oxide resistor supplier: 2011
-Carbon film resistors
Consumer Audiovisual Heritage
Production Process:
Carbon film resistor market: 2011
Top 14 suppliers of carbon film and carbon component resistors in 2009: market leader
Technology + Economics of Linear Resistance: 2011
The relationship between resistor engineering and end markets:
Figure 1.3: Resistor technology classification: SMD, through hole and network
Comparison of resistance capacity of linear resistance types: 2011
Figure 1.4: Resistance capacity divided by resistance type (in ohms): 2011
Comparison of tolerance capabilities of linear resistor types: 2011
Figure 1.5: Tolerance capability of resistor type (%): 2011
Comparison of power capability by linear resistance type: 2011
Figure 1.6: Power handling capacity of resistance type (Watts): 2011
Configuration comparison of linear resistance types: 2011
Figure 1.7: Configuration by resistance type (axial, radial, SMD, array, SIP, DIP and custom): 2011
Market and technology drivers of linear resistors: fiscal year 2011-2012
Figure 1.8: The relationship between linear resistors and their types and configurations and end markets in FY2011
The main technical and economic market driving factors of linear resistance:
Resistance in electronic circuits (the universality of the product line):
Equivalent to the physical size of the resistor (raw materials are the key cost factor in production):
Miniaturization trend:
Integration and modularity trends:
-Thin film technology (NiCr, TAN)
-Integrated passive components
-Flip chip technology for DIP and IPD networks
-Lead-free impact on resistance
-The sulfur resistance trend of thick film chips
Market strategy of resistor manufacturers: 2011
Single product focus
Broad product line
High growth product portfolio
Note on other resistor markets (non-linear and variable resistors):
The global market for linear resistors in fiscal 2011:
Figure 2.0-Global market value, sales volume and average unit price of linear resistors: 2007-2008-2009-2010 fiscal year actual and 2011 forecast
Global resistor market forecast: 2003-2010; 2011-2015F
Figure 2.1-2003-2010 and 2011-2015 fiscal year global shipment forecast of linear resistors
Figure 2.2: 2009-2011 fiscal year global resistor consumption forecast according to the 2012 fiscal year forecast:
Thick film and thin film chip resistors: 2010-2011-2012 forecast
Networks, arrays and integrated passive devices: 2010-2011-2012 forecast
Threading resistance: (wire wound, nickel-chromium alloy film, tin oxide, carbon film, etc.): 2010-2011
Global shipment value by resistance type: 2003-2010; 2011-2015F
Figure 2.3-Global shipping value by resistance type (thick film chip, network, nickel-chromium alloy, tin oxide, foil, wirewound and carbon): 2003-2011; 2012-2015F
Five-year resistance forecast: 2010-2015:
2003-2010, global shipments by resistance type; 2011-2015 forecast
Figure 2.4: Global shipments by resistance type: 2003-2009; 2010-2015F
2003-2010 global average selling price of resistors 2011-2015F:
Figure 2.6: Global average selling price of resistors by type: 2003-2009; 2010-2015F
Figure 3.1: The delivery time trend of linear resistors, by resistor sub-type: 2010-2011
Figure 3.2: Delivery time (weeks) of thick film chip resistors by case size in 2010 and 2011
Figure 3.3: Delivery time of axial and radial lead resistance, by type, 2010 and 2011 (weeks)
Figure 3.4: Resistor network by type (array, SIP and DIP) lead time (by month), by 2010 and 2011 (week)
Figure 3.5 Delivery time (weeks) of THIN thin film chip resistors by housing size in 2010 and 2011
Passive component raw material price index: base metals to the south, precious metals to the north
Figure 4.1: Index showing the total cost of raw materials used to produce passive components
Figure 4.2 Index shows the total cost of raw materials used to produce passive components by material type and month 70
Forecast of regional consumption of linear resistors at the end of the year
: 70 Asia: Resistor consumption forecast and growth rate in fiscal year 2011:
: Forecast value and growth rate of resistor consumption in FY2011:
Americas: Resistor consumption forecast and growth rate in fiscal year 2011:
Forecast of linear resistor consumption by region in 2010 and 2011
Linear resistor consumption by end-use market segmentation: forecast and update as of March 2011
Figure 6.1 Product sub-categories broken down by end-use market: 2011
Changes in Resistor Consumption by End-use Market, 2010-2011 FY
Figure 6.2 Top linear resistor manufacturers and their revenue by end-use market segment: fiscal year 2009 ending in March
2011 consumption forecast by end-use market:
Figure 6.3: Demand value of linear resistors segmented by end-use market: 2007, 2008, 2009, 2010 and 2011 fiscal year forecast
Outlook: global consumption of major electronic components; passive electronic components: 2009-2010; 2011-2015 fiscal year forecast
Personal computer market segmentation: FY2011 update and 2015 forecast revision
Revised global shipments of notebook computers and netbooks by 2015
The impact of the resistance market on 2015:
Global computer printer shipments revised to 2015
Telecommunications market sector: fiscal year 2011
Revised global wireless handset shipments and forecast to 2015
Revised global wireless LAN box shipments and forecast to 2015
Consumer Audio and Video Imaging Market Segmentation: FY2011 Update
Revised TV and forecasted global unit shipments to 2015
The impact of the resistance market on 2015:
Revised global unit shipments of DVD recorders and forecast to 2015
Revised global unit shipments of video game consoles and portable video games to 2015
Revised global unit shipments of portable audio/MP3 player games to 2015
Global unit shipments of digital cameras revised to 2015
Automotive market: Update for fiscal year 2011
Global car unit shipments revised to 2015
Power and Industrial Markets Division: FY2011 update
Global home appliance shipments revised to 2015
Revise the unit shipments of global lighting ballasts by 2015
Special electronic market areas: FY2011 update:
Medical department:
Defense Department:
Other fragmented professional markets:
Oil and gas exploration electronics: (also known as downhole pump electronics); railway electronics: (power rail capacitors, detectors); laboratory test equipment: (high voltage and high frequency test equipment; lasers: (government, commercial, medical) Laser and power supply); TV transmission equipment: (transmitter and special camera; strobe light {buoy and beacon; airport lighting equipment (various special equipment) strobe); welding equipment (power film); mining electronics: (railroad Branch of electronics; mining equipment); agricultural electronics: (agricultural equipment)
The current market changes that will drive the demand for resistors in 2011-2015:
The proliferation of touch screen interfaces:
Mobile phone convergence: 2011-2015 fiscal year
802.11a and MIMO in wireless LAN boxes: 2010-2015 fiscal year:
Future Trends: Networked TV, Multi-standard Media Decoder and Inductor Market: 2010-2015
The transition to digital television standards in developing countries: 2010-2015.
The sales of HD TVs are closely related to the sales of DVRs.
Most people in the world still receive TV through analog channels
BRIC countries adopt red light DVD:
Opportunities in the emerging automotive DVD market
Blu-ray and upconverter DVD trends: 2010-2015:
Video game market outlook: 2011-2012 upgrades and MEM
Electronic devices for electronic gaming companions: new market opportunities
The next generation of portable gaming trends: 2010-2015
The main growth driver of portable audio players: 2010-2015
Digital Cameras: Technology Trends and Directions: 2010-2015
The upcoming changes in camera technology: 2010-2015
The development of HD hybrid cameras: 2010-2015:
Digital cameras with Wi-Fi function: 2010-2015:
Digital single mirror reflection (DSLR) technology:
Netbooks: Unit shipments in 2011-2014
The growing demand for hybrid vehicle technology
The hybrid solution should change the amount of passive content per car:
Transmission and distribution capacitors for smart grids:
Important market opportunities for manufacturers of high-voltage power components:
Lighting ballast and LED
From 2011 to 2015, six new consumer technologies will grow the resistor market:
Changes in the global market share of passive electronic components in fiscal 2011
Figure 7.1: Global suppliers of passive electronic components: FY2011 forecast market share.
Resistor Suppliers: Global Sales and Market Share: FY2011 Forecast
Figure 7.4-Linear resistor manufacturers: Estimated revenue changes: 2008, 2009, 2010 fiscal years
Resistor Suppliers: Global Sales and Market Share by Component Type: Changes in FY 2010-2011
Chip resistance:
Market share of thin film resistors:
Thick Film Chip Resistors: Global Market Share: 2010-2011 Fiscal Year
Network: 1
Resistor network, array and IPD market share:
Resistor Network, Array and IPD: Global Market Share: 2010-2011
Vishay: thick film and thin film resistor networks and integrated passive components; over the years, the company has acquired multiple brands, and Dale is the core of Vishay's resistor business.
Panasonic is good at participating in a large number of multi-chip resistor arrays; there are also various custom resistor configurations.
TT Electronics: Including IRC thin film network and BI thin film network (formerly known as Beckman).
KOA includes KOA thin film network and TAMA assets.
Hokuriku is involved in array production and high-voltage networks.
Rohm produces multi-chip arrays like Walsin. CTS and Bourns produce DIP networks.
Through hole:
Through-hole resistor market share: FY2011
Puncture resistance: global market share in fiscal 2011
Major Market Segmentation Intelligence: FY2011
Vishay:
Huaxin:
Yageo
ABCO ELECTRONICS CO. , LTD.
Akabane Electronics Industry Co., Ltd.
Alpha Electronics Co., Ltd.
BARRY INDUSTRIES, INC.
Beihai Yinhe High-Tech Co., Ltd.
BI technology (TT Electronics)
Burns Corporation
CADDOCK ELECTRONICS, INC.
CAL-CHIP ELECTRONICS, INC.
Chaozhou Sanhuan Co., Ltd.
Xintai Resistance Co., Ltd.
CLAROSTAT MFG. COMPANY LTD.
C-MAC Micro Technology
Herbastar Technology
Union enterprise co., ltd.
CTS CORP.
Dannan Co., Ltd.
Diab industrial co., ltd.
Dongguan Shihao Electronics Co., Ltd.
Eberg Electronics Group
Yonghong Technology Co., Ltd.
Fenghua Advanced Technology (Group) Co., Ltd.
First Resistance Capacitor Co., Ltd.
FIRONRONICS components
Fukushima Futaba Electric Co., Ltd.
Hanlong Electronics Co., Ltd.
HMR CO. , LTD.
Hokuriku Electric Industry Co., Ltd.
Huntington Electric
HYMEG Corporation
IMS-International MFG Service (IMS)
IRC-TeTePLC
IRC line and membrane technology-TTePLC
ISABELLENHA? TTE HEUSLER GMBH & CO. KG
ISOTEK Corporation
Iwasaki Chemical Co., Ltd.
Japanese resistor MFG. Limited company.
K-TRONICS, INC
Kamaya Electric Co., Ltd. (Watson)
HKUST
KOA SPEER ELECTRONICS, INC.
KRL / Bantry Components, Inc.
METALLUX SA
Meritek Electronics Co., Ltd. (PANJIT)
MICRO-OHM company
Merrimack Industries Ltd.
MINI-SYSTEMS, INC.
MMC ELECTRONICS United States (KAMAYA)
NIC COMPONENTS CORP.
Nikko Corporation
OHMCRAFT, INC.
OHMITE MANUFACTURING CO. , INC.
OSI Optoelectronics
Pacific Resistor Company
Panasonic Electronic Equipment
Phoenix Passive Components Receipt (VISHAY)
POWEROHM Resistor Company
Precision Resistance Co., Ltd.
Precision Resistance Products Co., Ltd. (PRP)
PRIME TECHNOLOGY, INC. /General Resistor/Shurite
Xinglong Electric Co., Ltd.
Q circuit
RALEC ELECTRONICS CORP.
RCD COMPONENTS, INC.
RFE INTERNATIONAL, Inc.
Riden
RIVER ELECTRONICS PTE. LTD.
Rom gmbh
Royal Electronics Factory (
) Limited
RUWIDO AUSTRIA GMBH & CO.
Samsung Electromechanical
Sanxin Electric
Sichuan Yongxing Electronics Co., Ltd.
Intelligent Electronics Corporation (Korea)
SRT Resistance Technology Co., Ltd.
Jingbao Electronics Co., Ltd. (SEI)
The most advanced company (SOTA)
SUSUMU CO. , LTD.
SUSUMU-Thin Film Technology Company (TFT)
Xintong Technology Co., Ltd.
Freshman Electronics Co., Ltd.
Taiyo Electric Co., Ltd. (TAIYOHM)
TALEMA ELECTRONIK GMBH
Tokyo National Industrial Co., Ltd.
TEPRO-VAMISTOR
Taibao
TOKEN (Token Electronics Industry Co., Ltd.)
Thin Film Technology Corporation (SUSUMU)
Tokyo Universe Electric Co., Ltd.
TTePLC
Viking Technology Co., Ltd.
VISHAY INTERTECHNOLOGY, INC.
Witrom (YAGEO)
Huaxin Technology Co., Ltd.
WILBRECHT ELECTRONICS, INC.
Yageo
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The passive component industry (manufacturers of resistors, capacitors and diodes that are found boring but vital in every electronic device) is on the verge of shortage. You can always buy a 220Ω, 0805 resistor, but instead of spending 2 cents for a penny like now, it's better to buy one in the near future.
Yageo, one of the largest manufacturers of surface mount (SMD) resistors and multilayer ceramic capacitors, announced in December that they would not accept orders for new chip resistors. Yageo cut production of cheap chip resistors to focus on high-margin niche market components for automotive, IoT and other industrial uses,
. Earlier this month, Yaego resumed accepting orders for chip resistors, but
(For articles behind the paywall, please try to click
).
As a result, there are rumors that the sales volume of passive components in the Shenzhen electronics market is very high, and several tweets from the electronics industry say that the prices of certain components have doubled. Because every electronic device uses these "bean-shaped" parts, reduced supply or increased prices means that certain products will not be shipped on time, profits will decrease, or the price of the latest electronic products will increase.
The question remains: Are we on the verge of a shortage of resistors, and what does it mean to have a manufacturer without the required parts?
With the upcoming shortage news, you can expect dealers to increase prices, buy more inventory or take measures to ensure a stable supply of SMD resistors in the next few years. There are two ways to determine whether this is happening. The first is an advanced analysis from a company that analyzes thousands of BOMs and provides engineers with tools to determine the right components for their supply chain. The second method is to check some old Mouser invoices.
In the past, I have purchased several rolls of Yageo resistors, and by looking at Mouser’s order history, I found that there is no change in the price between six months ago and today. In June last year, five thousand 220Ω, 0603 resistors from Yageo cost $10, while today's cost is $10. Of course, this is a data set. To truly understand the inventory situation, we need better data.
, A search tool for electronic parts (owned by SupplyFrame, the owner of Hackaday and the person who pays me) has a "parts intelligence" tool for viewing historical prices and inventory of various parts. For example, Yageo’s stock
News about potential shortages of important commodities such as chip resistors and capacitors may scare some people. Of course, there is an obvious question: should the company stock these bean-shaped bean parts? Should you lock in the price now and buy a full year of inventory? What if
Did something? History tells us that you should not do this.
In the early 1970s, there were a lot of consumer goods shortages in the United States, the most important being the shortage of natural gas. However, there is another way to gain insight into why you should not store more than you need during a shortage. In 1971, a corn blight hit crops in the southeastern United States, increasing the price of livestock feed. In response, livestock producers reduced their herds, and the price of meat (especially beef) rose sharply. By 1973, the media reported a shortage of beef and consumers complained about the high price of premium steaks.
Also in 1973, William Rathje, a young archaeologist at the University of Arizona, began studying garbage. The garbage hidden in the household garbage bags collected in 1973 is garbage, which surprises anyone concerned about the shortage of beef. Under the grapefruit peel and coffee grounds, he found a well-preserved T-bone steak wrapped in a paper towel. Other garbage bags unearthed during the first season of Rathje
Shows more beef chunks, which is completely edible on the surface. In these bags, you can also find newspapers reporting on beef shortages, and the results of media investigations clearly show that consumers are reducing beef consumption. In fact, the analysis of garbage shows that during the beef shortage period, consumers buy three times as much beef as before or after. Consumers stock and panic buying without realizing that beef is perishable. Others bought cheap, unfamiliar pieces of beef that they didn't know how to prepare. During the beef shortage, beef consumption increased. Human psychology is strange.
The moral of the beef shortage story is to buy what you can foresee, not what you worry about not getting. In our current situation, implementing the latter will result in component reels not being used in racks and closets around the world, rather than being available when needed. The damage rate of resistors is not as fast as T-bone steak, but no one likes to carry too much inventory, and the act of hoarding will definitely allocate scarce resources.
Unnecessary inventory may be bad, but the electronics industry is also strange. There is no other industry on earth
Can buy supplies of certain things in the world. Myself
Furthermore, the market for commodity resistors is different from the market for rare components. Among rare components, being able to purchase parts will destroy product release. This may be a temporary error. With sufficient inventory there, market forces will eventually prevail, requiring resistor manufacturers to increase production lines and produce thousands of resistors. But before that, we are likely to see higher prices for chip resistors, which may increase the BOM cost by a few cents.
The box of resistors under my bed might turn into a gold mine!
"The moral of the beef shortage story is to buy what you can foresee, not what you worry about not getting."
Or ethics might be, learning how to store and prepare what you have?
As for non-perishable things like resistors, it may be worse that they are useless. Likewise, maybe people will be able to 3D print their resistors in the future.
Make it jerky, it will stay longer...
Uh, uh! Thin carbon film dry is the best!
Oh, you just can't resist, can you?
thank you all. Make full use of the entire reading time.
For "better", for everyone, if no one stores unwanted resistors, that would be the best choice.
But the problem is you: "If...the best"...will not affect everyone's behavior, so there are rumors that resistors may be short in the near future, which will lead to actual shortages in the short term. They will not be wasted like beef, but they will be piled up for a long time...
Well.. When a large passive house is smaller than a grain of sand and we are all old and unable to adapt to any architectural style allowed.. It is the hoarders who will sell their second-hand goods on Ebay, and their The children sell garbage dumps. In the death table or worse, put them in the big cardboard box under the big table and go to the old man's house so we can continue to build things.
Indeed... I plan to buy a lot of resistors: P
This was the basis of British rationing during World War II. There is a limit to the amount of X/Y/Z you can buy, but in return, the government guarantees that you can always buy X/Y/Z, so you don’t need to buy it until you need it
InRange viewer detected!
Global resistors are more difficult to debug. I prefer object-oriented electronic devices. My parts are local (and start with an underscore).
If we really need the resistor urgently, we can try to connect the electrode to the preference function instead of the object-oriented heresy!
However, then you will not be able to use OO resistor arrays.
Okay, you have to share this... How did you accidentally monopolize the entire supply of scarce components worldwide?
I clicked on italics, hoping to find the answer link!
Yes, I want to hear that story too. . .
This is easier than you think. I did this (intentionally) the other day. Mouser and the smaller houses are gone, there are only a few hundred digital keys left, so we bought all of them. prosperity. Global shortage [exaggeration]. But until the manufacturer delivers the next batch of products (such as 2 months). In this case, it is a special 5-pin RA circular connector.
I am also curious about the "accidental" part :-)
I used to be the largest purchaser of Rogue Imperial Stout in the country. It turns out that no one bought this product at that time. I happened to work at a distributor and bought a box on behalf of a friend. $13 per bottle (distributor pricing), bars and restaurants only buy a few bottles at a time, mainly for decoration.
My purchasing colleague received a call from the Rogue salesperson and confirmed that this is not an error.
Thieves Empire Stout
Was this name brewed by fans of Star Wars?
Don’t I drink much beer? The gangster is the brewery, and the imperial stout is the style. I cannot comment on their preference for movies.
I'm sure this is related to SMD LED...
The topic of discussing the market is a bit off topic, but it’s really good: here is a link to the 2015 NPR story about the monopoly of the entire American onion market in 1955.
I think this is the LED panel they used for badges about a year ago and then modified to bare LEDs.
I actually did it almost once. In other words, my subcontractor did it. They are making two circuit boards with specific contact information for me. When I am making revisions and preparing to purchase some additional components for my own testing, I find that I can’t find the parts I want, so I call my Branch office. -Contractors, and ask them if they have these components, because I can't find them. Obviously, they bought all of them.
This story repeats itself from time to time, so I may be more general than people think, especially when the components you use are not the most common ones.
A large part of the problem is the small increase in demand (the current global economy is relatively good) and the drive to continuously reduce the cost of electronics. So far, component manufacturers can only reduce costs, and many manufacturers are already at a loss. Now, there is no incentive to invest funds in new passive component factories. They will make as many resistors as possible, and no more resistors. In a sense, I think we may have found the intersection of the price/demand curve on the material.
I am not a real economist, I just work for a relatively large component manufacturer, which is basically what they told us. I am not directly involved, but in the daily conference call, some small parts manufacturers ask for more resistors, we must tell them "No, not for now." Every day has the same questions and answers, everyone will go Ape. The flood of counterfeit goods into the market seems to be the best situation, so please be careful.
Fake resistance?
This reminds me of my attempt to make a power resistor with a pencil lead. Short story... they can't dissipate too much power.
Why smoke-increase the voltage and create a carbon arc!
Just for it, I went to Digi-Key and checked a 220 ohm, 0805 resistor.
There are 10 suppliers for this part and there are millions in stock. That is from a distributor. I think we will be fine.
People often do this. When something extremely cheap becomes expensive for a penny, we seem to see a certain end of the world, as if it will disappear, and we must start hoarding it now. I think people secretly hope that the world will end or something else.
Wait until the GPU market collapses.
Bitcoin needs to implode first: P
Who is mining Bitcoin with GPU?
They are mining Ethereum and other alternative coins that do not use SHA-256 or scrypt for proof of work. It seems to be profitable because the shortage of GPUs (as well as high-end power supplies, low-end CPUs and ≥4 socket Mobo) continues.
The price of alt coins often changes in sync with Bitcoin, because confidence or lack of Bitcoin will spread to ultra-small cryptocurrencies. If Bitcoin explodes, all other Bitcoins may also explode.
However, Digi-Key cannot well represent large-scale supply and cost. The basic resistor is so cheap that about 90% of the Digi-Key price is high, which makes the price difference less obvious (usually the correlation with the wholesale price is not very good). Most of the parts are sold directly from the factory to the PCB assembly plant, where switching from Yageo parts for $9/reel to Panasonic parts for $40/reel is not a "sure, no matter, no one" decision. It will not suddenly make the manufacturing of smartphones unprofitable, but low-end products that are already profitable may encounter some problems. These price changes will have to spread throughout the chain, thereby breaking the previously agreed contract and timetable.
It may not be eliminated, but it will definitely change some business models. Remember the chip? Those guys went to great lengths to make things as cheap as possible, so that they used composite video output instead of mini-HDMI. It may not be a big deal here and in most places, but when your fixed price is your whole selling point, you may have to increase the number of pre-orders to maintain the same pricing structure, and this will make you early now have to either commit To buy more products, either act as a PR and gain their success to spread the information to the adopters.
What happened to CHIP?
They went bankrupt.
Too bad, I want to use GR8 SoM in a project, but I cannot buy any CHIP Pro, nor can I buy any CHIP Pro.
Not just low-end, low-profit. People are willing to spend a lot of money on smartphones rather than on dishwashers, but which ones do you think will cost more?
I am very happy that the products that I design sell only a few hundred or less each year, and they are expensive. For my (relatively) small batches, it doesn't matter if my resistors cost 1 or 2 cents per piece. Compared with many other costs, it hardly reduces BOM costs.
me too. Usually, if the passive scroll price increases three times, I won't care. I just need to be able to get them. However, recently I encountered a serious problem with ceramic capacitors. Not just resistance. I have a new revised version of the CPU board, and the footprint was changed entirely due to supply issues to allow 1210 and 1206 on larger capacitors.
In fact, I think it’s ridiculous, just like I have been successful for 7 years without experiencing a serious shortage of distributors, I can’t solve it somehow (have to make a few calls) and finally reach what I can afford To the extent that everything is stocked into the manufacturer’s lead time requirements... Now, these lead times are blurred and no longer reliable.
Thanks to Joe Kim for another great graphic!
In global economics, if the required products are missing, alternative methods will be found.
Therefore, if one factory in China cuts or stops producing resistors, I believe another factory will start producing them, whether in Vietnam, India, Malaysia, Angola or Timbuktu...
Of course, Yeago may be another DeBeers...
Maybe.
Maybe there was a surplus before, this is a market adjustment. I like that anyone can buy cheap parts, I hope that is not the case, but you must admit that it is a small doubt to be able to buy anything for years for a few dollars.
In addition, even if there is no oversupply, there is indeed a shortage now. It will take some time for other companies to realize the gaps, decide to fill the gaps, and provide tools for factories to start production and distribution. At the same time, if this news triggers a lot of panic buying, we can at least expect prices to rise temporarily.
The memory market is already in contraction.
Resistors are easier to produce than large-capacity memory chips. They are even produced in Europe:)
Need a 3D printer to make our own
Not only Yageo, I am a component/continuation engineer. Basically all passive component manufacturers are receiving notifications telling us that the market is entering the "allocation" phase. When you buy 3.1 million parts of a given part every year, it is painful to be told that only 750,000 parts will be sold.
When you get parts from each of the big-name manufacturers in the qualified list, you will also find that none of the parts can meet your needs in the last month, which is also very painful (Want a 649ohm 2010 package resistor? I wish you Good luck! We have never heard of "Viking America" before, obviously they have some.)
Most manufacturers expect a market bubble sometime this year. They don't want to stay in inventory, nor do they want to invest in equipment that may be idle in a few months. The little guy trying to fill in the gaps is completely unknown in many cases (and we avoid dark gray areas when I work on personal safety) and cannot keep up with the needs of other people.
Usually diodes are not counted as passive components, right?
Of course we have already had this conversation ;-)
In the past 4 months, the delivery time of Yageo MLCC of our main distributor has been changed 3 times (stretched)! It looks like capacitors will be the next... :(
There is a continuing shortage of capacitors in Shenzhen.
For example, the price of capacitors in the EOMA68-A20 computing card dropped from 0.5 usd to 2.5 usd.
This is much better than the worst 4-8 usd number cited a month or two ago.
But it is still increasing substantially.
"There is no other industry on the planet that can randomly buy anyone's things."
For all the kids who don’t realize how great they are these days...
I think this is a common strategy before the Internet era. Buy all the parts and design a project around it. Then publish the item in fan magazines (such as "Popular Electronics", "Radio Electronics", etc.)... In the beautiful printing of the BOM, mention your address, and you will be happy to help users find hard-to-find parts Some inflated prices.
Lol
Today, if you try to list 10 common alternatives in forum comments within an hour.
"I, myself, did it by accident."
Oops, come on Brian. Now we all want to hear this story. The way to make fun!
Now, I really want to know the story of Brian buying something in the world by accident.
Did you mention the vertical sodimm sockets when you discussed the Pi computing module?
I have been looking for those, they seem to be as rare as hen teeth.
Oh yeah. Forgot that. That's just
The supply of the world is somewhere in my basement.
This seems silly to me. This is not like a capacitor disaster. There is no "secret recipe" for making chip resistors. They are commodities. Yaego doesn't want to make them anymore? Panasonic will only speed up the pace. Or Vishay. Or Stackpole. Either...
Maybe Yaego will start producing resistors again. I see a lot from commodity manufacturers. They cut the product line because it was unprofitable, the market panicked and raised the price, then the company restarted the product line, and now they can sell it again for profit. In some cases, manufacturers manipulate the market so that even if the price drops below the level before the shortage, they can finally afford the upgrade cost of the machine and still make a profit.
The moral of the story: cryptocurrency is dead; buy resistors!
It might be a good idea to work on a cheaper micro Waldo system to make better use of the parts that will be available.
Major distributors are now quoting aerospace-grade capacitors and resistors with an average lead time of 65 weeks. Yes, there is a shortage.
My work team bought very special sensors worldwide, but still no stock
If people want to know... I think this is what Brian refers to as an "accidental" global supply shortage:
Then it was time for Hackaday to purchase all 38mm Kingbright common anode 8×8 LED displays (red and green), and Voja had to rotate some common cathode compatible badges and rewrite the software to automatically detect which displayed it.
And there are only 270 badges. This is why the next iteration has a loose LED matrix.
I admit to buying a few rolls recently...but not because of this.
There happen to be 1k and 10k resistors, sometimes 100k resistors dominate my design, I use 1206 or 0805. I may get some reels with other values, but basically, maybe there are 10 values, I don’t see that I have bought a lot of reel resistors in great demand. Although there are many commonly used values, I don’t take up much time, so the price is 10 Australian dollars each time, why not?
I actually encountered quite a problem when I got a cut-off resistor at 0805. I didn’t have any problems at all before. This caused panic among the manufacturers. I rushed to buy them directly from many manufacturers to prevent embarrassment and Time-consuming mass production
According to Digitimes, “Yageo is cutting the production of cheap chip resistors to focus on high-margin niche market components for automotive, IoT, and other industrial uses.”
I know that AEC Q200 certification may increase the requirements for automotive parts and reduce costs, but why do you need any special passive components for IoT devices or standard industrial applications?
It looks more like they want to (ab-) use their global market power (they have approximately 30% market share in passive components) to drive price increases and satisfy shareholders...
The shortage of MLCC is real. We have heard from all suppliers, not just Yageo. Some publishers still have sufficient inventory, but do not trust the prices on their websites. It changes every day. The resistance is not bad, but it will definitely rise. We buy most resistors and capacitors from American manufacturers. If there is no inventory, it is usually possible to produce commercial-grade products at a price of 1-2 weeks and military products (including aging) at a price of 3-4 weeks.
It can probably explain why from the 6 0805 reels I recently ordered from Farnell, I only received 0R.
Although I may accumulate 5000 items for 5000, it is basically a MOQ... and I don’t think I will accidentally cause a shortage of supply :)
Hey MB, who is an American company that produces commercial grade resistors for 1-2 weeks and military resistors for 3-4 weeks (including aging)? Is it Vishay? The offer I got from them is much longer.
It looks like this started in October and will continue until at least mid-2018.
. It may be related to the recent currency fluctuations or China's debt bubble. No matter what method you take, the era of cheap Chinese-style products will soon end.
It will only move to other countries such as Vietnam or the Philippines.
This reminds me of the 4000 series of logic chips about ten years ago. Several large manufacturers have decided to use their fab capacity for higher costs than packaging, and the price increase is enough to induce at least one of them to return to production.
"There is no other industry on the planet that can randomly buy anyone's things. I did this by accident."
Do you have an article about this story? I want to read.
Or is it like buying 10 raspberries on the first day?
Dennis, the answer to your question about the company that produces 2wks (commercial) and 4wks (military) resistors is not Vishay. It is the RCD component of New Hampshire, USA. They are one of the old timers that started 50 years ago.
Very useful when looking for replacement parts for out-of-stock capacitors.
The shortage of memory and multilayer ceramic capacitors (MLCC) slowed the delivery of customer premises equipment (CPE) products. As a result, CEO Bruce McLelland said on today’s earnings call that some production will be transferred from the second quarter to the third quarter. "
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Sometimes you may need an odd value resistor. Without spending money to buy a 3,140Ω resistor in the store, you can bring a good ohmmeter and be willing to solder in series and parallel. But when you want one
Resistance value, and you need many resistance values, then repeatedly combining many Frankenstein resistors together is a bad solution.
Like 8-bit
For example, 17 two-value resistors are required, and the accuracy is better than 0.4%. This is just something I don't have on hand, and the serial/parallel approach will quickly become boring.
A long time ago i read
, But suppose this is the realm of lunatics. On the other hand, this is Hackaday; I have some time and documents. Can I adjust and match the resistance to within 0.5%? Please read carefully to find out.
Your ordinary through-hole resistor is
It is made by depositing a thin layer of metal on a non-conductive ceramic cylinder. The metal film is cut into a spiral shape, and the length, width and thickness of the resulting metal coil determine the resistance. Since the deposited metal is so thin, between 50 nm and 250 nm, you might think it would be picky to trim it by hand.
Jump directly to the key point. When I try to change the resistance by a small amount (maybe less than 5%), it is very easy to accurately drop the point to the exact expected value. I have bags with 1kΩ and 2kΩ 1% resistance, and I think I will make a lot of mistakes while studying.
The reality is that I exceeded the target once in seventeen attempts and only completed one ohm. I can measure the remaining resistance and fine-tune it-down to a single ohm. (My meter and probe have an offset of 0.3Ω, but there is nothing I can do.) I made a tip for the "bad" probe, made another one, and had a perfect setup in a short time.
This is the whole process. I put the resistor in some insulating clips and fixed the ohmmeter at both ends. I used a small round file and went. The first few strokes allow you to pass through relatively thick coatings, but once you see metal or spot a spot on the ohmmeter, it is usually a light touch with a file. As you approach, you may blow off some metal dust between the brush strokes, but I didn't notice a big difference. Seven or eight taps were performed on the small, lightweight file, bringing the resistance down to ten points.
Indeed, because it was too easy at first, I found that the ideal candidate resistance was 1,990Ω. Many of my 1kΩ resistors are introduced with 999Ω resistance, which makes it difficult to pass through the case without exceeding the mark. I may have just left them. The good news is that most 1% resistors will have a resistance of more than a few ohms in both directions, otherwise they will be sold at 0.1% resistance. Of course, you need to choose a source resistance with a lower resistance than the target resistance-you are not
Metal and documents.
Therefore, only one resistance value is needed in the kit, right? Absolutely not. It is troublesome to create a 1.2kΩ resistor with a 1kΩ original resistor. I made it work several times by restarting the archiving process in another location instead of simply going deep into a hole, down to one ohm again, but I don't recommend this, I don't know when you need it. Just connect a 200Ω resistor in series and adjust it. Remember, you are starting to thin out metal spirals with a thickness of only 100 nm. easy.
It is much easier to set the through-hole resistor to the value accurately than I expected, so I decided to take more difficult measures. I nailed a 1206 2.1kΩ resistor on a peeling board. Don't you know, it reads 2,100Ω accurately, so 2,105Ω becomes the target. That's not good at all. I ended up with a 2,722Ω resistor that was faster than expected.
The second 1206 started at 2,103Ω, and I just tested it without a target. By operating very carefully, I got resistance
To 2,009Ω, then jump to 2,600Ω or even higher. There is no point in reducing resistance at all. Maybe I dragged some solder into the gap and effectively thickened the metal layer? I have been looking for information, but there is no deeper understanding of the structure than Vishay's data sheet: "Metal glaze for high-quality ceramics" is not much inspired.
After two more attempts, I couldn't adjust the SMT resistor at all. The deposited metal layer is too thin. And, anyway, I'm not sure how useful this will be-the 17 ideas of soldering and desoldering are not very attractive.
Trimming through-hole resistors is awesome. I made a complete set of matched resistors better than 0.05% (!) for an 8-bit DAC in half an hour, with only a file and an ohmmeter. And in my first attempt. You can easily make a 10-bit DAC in this way. The result was an order of magnitude better than I had hoped, and it was not difficult at all. amazing. There is nothing cooler than a handmade handmade DAC. (For odd-numbered cool.)
On the other hand, my attempt to trim surface mount resistors completely failed. Does anyone care to guess why? Is it just the clumsiness of cutting ultra-thin film? Anyone who owns a precision laser cutting machine wants to go
?
Usually, you don't need an exact value, but a constant value, so you need an expensive resistor with a very low temperature coefficient.
I want to know PTC and NTC in parallel or series. Do you think that if you find a good match, you can do it?
Resistors sold in the form of PTC or NTC generally have a large temperature coefficient and are generally not linear. If you want to minimize the effect of temperature, it is best to choose a conventional (precision) resistor and find two resistors with opposite temperature coefficients.
The temperature coefficient has almost no effect on the DAC, because the resistance ratio is calculated. As long as you install them close to the heat source, it does not help at all.
I know it doesn't matter for DACs, but this is not the only application for precision resistors. I mainly use them for Pt100 measurements, so accurate values are not as important as stability over time and temperature (I can use precision benchmarks for calibration).
So: quickly dip in epoxy to reseal them, and then install them in contact with each other?
Allen: That's what I want to say. Before IC operational amplifiers, there was an old trick that was common when constructing differential amplifiers: Wrap the transistor pairs with an aluminum tape to keep the same temperature at the same temperature. Yes, maybe something similar-apply the entire R-2R ladder to a strip of aluminum.
@ [BrightBlueJim]
You can buy two transistors in one die and the same 6-pin package. It even has its own TO-xxx number. Not sure, but I think this is an NPN PNP pair.
Yes, I have seen these, but they are usually much more expensive than two transistors.
You just described a 5.6 volt Zener diode. In any case, Zener/op amp or comparator will always provide a better reference.
This is why the internal ADC reference voltage on the microcontroller is not very accurate or stable. You can use the IO pin for a voltage doubler/charge pump, so you can have a 5.6 volt Zener, and use a resistor to divide it back below Vcc. If you use an active crystal oscillator, you can use unused passive crystal oscillator pins instead of IO, but because of the higher frequency, the design is a bit tricky.
For almost the same reason, you can use a normal diode (forward biased) as a temperature sensor. Their voltage range is very small, but you can use two diodes as ADC reference voltages in the same thermal environment and can provide a ratio that can be calibrated based on temperature. Two diodes will provide about 1.2 volts-sounds familiar?
Zener voltage is sensitive to temperature and current.
1,2V may sound "familiar", but usually they come from a circuit called a "bandgap reference" that uses some physical parameters of silicon that are (or at least not closely) related to a forward voltage (Or not closely) related. Two) Silicon PN junction.
As a temperature sensor, you can still use a transistor to amplify the diode voltage drop. Yes, transistors also depend on temperature, but temperature sensors are needed anyway. If the operation is correct, the extra diode can be omitted.
In fact, I read Bob Widlar's description of the bandgap reference circuit some time ago, so I can’t be 100% sure, but in my opinion, he said that the circuit will be forward biased. The voltage drop across the selection resistor increases the voltage drop across the selection resistor to eliminate the temperature coefficient. The band gap is the reason why the PN junction has a voltage drop of 0.6V.
From
Zener reverse breakdown is due to electron quantum tunneling caused by a high-intensity electric field. However, many diodes described as "Zener" diodes rely on avalanche breakdown instead. Both types of breakdown are used in Zener diodes. The Zener effect prevails below 5.6V, while in the above avalanche breakdown. "
"In silicon diodes up to about 5.6 volts, the Zener effect is the main effect and exhibits a clear negative temperature coefficient. Above 5.6 volts, the avalanche effect will dominate and exhibit a positive temperature coefficient. In the V diode, these two effects occur simultaneously, and their temperature coefficients almost cancel each other out, so the 5.6 V diode is very useful in temperature-sensitive applications."
Another way to consider film removal could be to use a laser. Once the focus is determined, it should provide you with more precise control over how much material you remove. This is also a method used in the industry.
"...The method used by the industry." Not many of us have powerful pulsed lasers at home. If you try to use any laser, let the resistance cool to room temperature after each shot, and then take the measurement. Micro-blasting is also used to trim the resistors.
"After each measurement, let the resistance cool to room temperature before measuring again"
Lasers used for laser trimming of commercial parts are not as powerful. I use a 10 mW YaG laser at my work place, but that is the resistance on the chip, not the high-power 1/8 W thin-film resistor. We need about 5 seconds to test and trim each part, so there must be no waiting time for cooling, but the test after trimming never showed any problems. The heating is very localized.
Yes, I can try it myself-after exposing the resistance element, I want to know how oxidation affects it.
Maybe some transparent nail polish or something similar to seal it?
Oxidation will almost certainly cause this value to rise. If you can prevent any moisture from staying under it, resealing it with varnish or varnish may help.
Made from 100% pure snake oil!
Epoxy glue?
I used this technique to fine-tune the resistance of the 555 timer circuit in the late 1980s. Equipping with a 4-wire ohmmeter will help. I didn't try it at that time, but wondered if applying a varnish or enamel coating would help.
In my opinion, if you are looking for accuracy, you need a calibrated 4-wire DMM, otherwise the lead length of your meter will still exist and the connection will add or subtract resistance.
Specifications of Fluke Model 12 ± (0.9% + 1)
And how long ago was the last calibration...
Or measure the wire resistance and subtract it.
…Then calibrate the resistance of the probe wire.
If you are only worried about the ratio, the resistance of the ohmmeter leads is the same. A 4-wire ohmmeter actually only works when you have a lot of numbers, such as HP3456 in ohm mode, or more commonly, when you are reading very low values and the wire resistance will be an important part of the reading.
In the past, I have used a low-value trimmer in series with 1% R, but this may not have the best long-term stability. I have selected cherry resistors with closely matched values and paralleled a higher value with a lower value to adjust the part.
The strange thing is that one of the devices I make that requires the closest component matching is a device that can quickly help select resistors.
Artenz: "Or measure the wire resistance and subtract it." We have a winner, or at least someone has read this article. :)
I mentioned that my probe has a 0.3 ohm setting. However, in thousand kilometers mode, it is lower than the least significant number, so I can't really subtract it. Or we can all pretend that I did this because it will not make any changes with the reported accuracy. Fourth line personnel-your answer.
As a group of people said, the absolute value of the resistance is not important, but just repeatability. I checked: a (single!) resistor, which is 2000 ohms, pulled it out of the setting, left it on the bench during my lunch, and re-measured at 2000 ohms again. Good enough for me. (I am rash, but in fact I am worried that my editing may increase the measurability of the settings, and cannot be measured.)
However, even for DAC applications there are problems. I am actually trimming 1 k and 2 k resistors. In order to correctly achieve the 1:2 ratio, I can use all 2 k resistors and connect them in parallel to form 1 ks. But what I use is actually adjusted 1 k resistor. Therefore, if my meter offset is 1% (10 ohms?), it will be 1.010 and 2.010 respectively. The ratio is no longer fixed. In the case of 8 bits, this is all too large.
But the point is, you will read on Interweb that the R-2R DAC is only suitable for five or six digits with commercial resistors. That's true, but by trimming it yourself, you can easily get a higher precision than the eight bits required. I am very excited, it seems I can score ten, but I cannot test.
Make sure you can (make measurements): Any error in the R-2R DAC will cause nonlinearity, usually in a non-monotonic form, that is, when you add codes to it regularly, the step size will not all be the same. In some cases, it will actually lead to a decrease in output, which leads to an increase in code. Since it does not require any precise measurement, it can be verified on an oscilloscope. You just use it to generate a sawtooth, and then zoom in on the waveform so that you can see each individual step.
You should choose the 2k resistor from the two adjusted 1k resistors. This way, if you have an offset of 1%, you will get 1.01k and 2.02k
Necro-comment: I actually made another way, the -1k resistor is two 2k in parallel. Each other.
Consistency is undoubtedly the goal here, so if 1k resistors are all read as 1k, but actually 1.0001k, but always 1.0001k, then it's fine.
It is assumed that the meters are at least consistent.
For DAC, as long as the value is the same, it can work normally. The actual value of the resistance is not as important as the difference between the resistances.
The ratio of 1:2 is also very important.
It looks like you can use a bare resistor as a touch sensor. I want to know how humidity affects them.
This is how the resistive touch screen works
Resistive touch is a sandwich structure in which one layer has a series of tiny bumps to keep the layers separated when there is no touch. There is no electrical contact with fingers or stylus.
Maybe it can, but bare copper wires, or screws, would be better. It should also be long-term reliable.
If the meter you use is out of the calibration range, a system error will occur. Although if you only need matched resistors, it is no longer a problem.
I am curious what effect this technology has on the power rating of the resistors-I bet they can handle less current after modification. May be an interesting thing! This is also a good way to see if repainting is beneficial, because the exposed parts may oxidize quickly due to heating.
Power handling depends entirely on heat dissipation. I suspect he will remove enough material to produce any effect,
I think the hot spot may develop in a thinner area, but it is so detailed that it may not matter.
Trimming a point always creates a "hot spot" because it reduces the cross-sectional area of the conductor, thereby increasing the current density at that point. In this application, a voltage of 5 V may be applied through about 4 kohm, which is only about 6 milliwatts, but in high power applications, this is definitely a problem. When the trimmed resistor fails due to excessive dissipation, it always occurs at the trim point.
If you look at the trimmed smt resistor or the resistor on the substrate, the trimming is done in an "L" shape. If the connection is considered at the north and south ends of the resistor, the coarse adjustment is in the east-west direction of the component, and the fine adjustment is in the north-south direction, which has a small effect on the resistance change.
This is indeed the case: the cut of the resistor is coarsely adjusted, and the one on the length is finely adjusted. Pruning is done very quickly, but the pruning will still show weakness (hot spots).
@Elliot Williams: You should check how time, humidity, light and vibration affect accuracy. Therefore, maybe only measure the resistance value again within a month or so, and then let us know the result.
The situation I encountered was 2 good resistors used to pull up some 74hc00 input lines. Even touch is enough to make the circuit inoperative from the beginning. Therefore, even enamel is not always a good insulator. Since then, I have maintained good spacing between the resistor and the circuit board and between each other.
The 74HC00 stuff is strange. I know CMOS is very sensitive, but still so. Maybe we can wire wound resistors (even like the spiral cut film in this article) to form a kind of transformer? Enough to couple a small current, but maybe enough voltage? It may be that there is a problem with them, and there is a problem with the insulating coating. What value resistors are they? In addition to the explanation provided, do you have your own thoughts on what happened?
They touched their bodies side by side. The terminal is not touched. This is because I tried to squeeze them to fit the 2.54 mm board spacing. They are usually 10 kOhm pull-ups.
No, I don’t know why this happens. The voltage is only 5 V, and the resistor will not overheat at any time.
When I separated them, the problem stopped.
"Their bodies were touched from side to side."
At first I thought it was completely out of date.
It sounds more like capacitive coupling.
Okay, I just made a set (original, trimmed, trimmed and nail polished).
Remind me within a month.
remind!
Okay, this is the Elliot of the future!
Short version: I remember testing the resistor in July 2017 and then forgot to publish it. They are all within 1 ohm of 2 ohms, which is equivalent to my measurement error.
It is April 2018 and the result is the same. (I remember b/c I just used nail polish in the same color as the insulator on another unrelated item.) Coated or uncoated trimmed (or untrimmed!) No measurable drift on the resistor .
This is the problem: I don't think leaving them in my desk drawer is a strong test. We do not have air conditioning, and the office is in the attic, so the temperature here can be as high as 30°C in summer and colder in winter (18°C?). But this is by no means absurdly hot, cold, humid or dry place.
I really like the idea of this experiment, but I have to take the resistor to the Spanish beach or elsewhere. Does anyone raise money for my vacation?
In any case, the initial (non-)result is: in the absence of challenging family conditions, the original trimming results seem to be pretty good. Sealed or trimmed is fine.
Now you have exposed the originally sealed resistor element to the environment. The final result (maybe earlier than you think, not later) makes the job of adjusting the resistance worse than the initial attempt. In any case, if you need this tolerance level in your design, either (1) your design is poor, or (2) choose from a reputable manufacturer and (important) a reputable distributor of that manufacturer’s components Parts with higher tolerances (for example, China = Dangerous).
This may be good enough for the application, and cheaper.
I want to know what effect the fine adjustment has on the rated power. Because you only trimmed part of it, I think the power rating drops much faster than the resistance increases
The power rating depends on the heat dissipation. The shape and size of the resistors are still almost the same, so they should not be changed.
I want to know the stability, air will enter it, will it attack it over time? A good test is to put the newly calibrated resistors somewhere in the drawer and forget where they are, simulating actual usage.
Then in a year, I accidentally bumped into them while looking for capacitors and measured them. See how they are doing. It will be interesting, there will be some scientific data, and you will get paid twice for the same article.
In addition, will it definitely make money for the handmade DAC in the handmade audio market? If they want to buy a sterling silver power cord, then they will definitely need a handmade, fully analog DAC. Even the DAC in the box is a component that the manufacturer will sell separately, getting a chip to do the S/P-DIF interface. The output can be some precision operational amplifier or valve.
"Fully analog DAC." That almost let me slip away.
See the Wikipedia article:
In the paragraph about unequal steps, they involve fine-tuning to the accuracy of the circuit, one bit at a time, rather than fine-tuning to the exact resistance value. They didn't go into details, but it also compensates for other circuit variables, such as switch resistance and operational amplifier offset.
However, if you want to enter the enthusiast market, you must pay attention to sealing resistors with oxygen-free epoxy resin after trimming.
I once walked into a high-end audio store. I asked the salesperson what the buzz was. She didn't know what I was talking about until I figured out the culprit-the power transformer in the $10,000 amplifier. I think at some point in the early 1990s, the better the audio. Since then, there has been concern about how to make it more expensive.
I think enthusiasts are now thinking about discovering how expensive test equipment must be to discover defects: D In engineering, this is still interesting, and in consumers, it is a waste of money.
no. It is not connected to the test equipment. It is a matter of finding the right marketing buzzwords to make people pay for something 100 to 1000 times higher than its actual value. It relies on close relatives whose placebo acts. Basically, people must believe that it sounds better than cheap equipment to justify their astronomical exaggeration. Otherwise, they will promise that they have made a costly mistake.
Basically electronic homeopathy. There are dozens of similarities in its psychology, methods, cherry picking, subjectivity, and experimental design around obtaining the desired results. The same weaknesses in the human mind, as well as the advantages of all the ways that aggressive, despicable people can take.
Advertising is one thing, only done correctly, not boring and amateurish.
Use (usually) open loop valve amplifiers to destroy the output of precision DACs? That is something that only listeners can like. :-)
When the distortion of the tube is increased by 5%, it will definitely produce "tube sound". Yes, the money is well spent.
This is common when ancient resistors were composed of carbon. They are like a carbon rod (inanimate carbon rod?), you can cut them with a triangular file. With so many materials, it is much easier to adjust, and there is not much to do with the wattage or current carrying capacity of the resistor. Seal with a little shellac.
As a former laser trimming engineer of the "major manufacturer", I think you might think the wrong way, Elliot. This is not the thickness of the material you are removing; this is some width. The total resistance is proportional to the length/cross-sectional area. On the spiral, by filing parallel to the edge of the metal, the resistance can be well controlled whether it is in the middle of the track or at the edge. The groove is considered very narrow. You have to be careful not to cross the conductor, as this will leave a little bit of power dissipation capability. (I have often encountered the problem of step attenuators on some RF equipment-their rated power is 1 W, but the fault frequency is much lower than this value. It turns out that they are laser cut into resistors, this is They all fail. .) The problem of SMD parts may come from two different aspects: 1) The area of the resistor is small, so you don’t have to remove too much material to increase the resistance, and the coating on the SMD resistor Too much can be difficult. My approach to SMD resistors is to polish or grind off the edges of the resistor area. Perhaps you can use Dremel with a cut-off wheel to cut in from the edge of the widest part. But I never really tried it.
Regardless, coatings on surface mount and lead components do more than just make them beautiful. This is to reduce water absorption, which will affect its value over time. After finishing, I should at least put a drop of super glue on the area where the coating has been removed. If you want your 12-bit DAC to maintain its accuracy, I will not believe that lacquer can provide adequate protection.
As for all discussions about 4-wire measurement and meter specifications, in the R-2R ladder DAC, the actual absolute resistance is only very large. The real important thing is to make them all match, so as long as you measure in the same way (same meter, same wire, same temperature, enough stabilization time), that should be fine. A 3-1/2 digit meter with a specification of 1% can still repeat to +/- 1 digit, which is .05% at 2 kohm, and you can even fabricate a number closer than this (even if you can't prove it) , If you can trim it to half the time it reads 2.000, the other half reads 2.001, because then you can be sure that it is close to 2.0005 k.
I also worked in a military avionics contractor. The contractor’s name cannot be said, and I was shuddered. They provided the location on the PCB for the critical adjustment of the two series resistors and then selected them in the test. However, are the resistors actually selected in these tests provided with the equipment? No, of course not, because testing technicians are not allowed to weld finished parts, and welding technicians are not allowed to make measurements. Therefore, once the test technician has fixed the appropriate resistors to the board, the welding technician will delete these resistors and obtain a new resistor with the same nominal value from the inventory (because it is not allowed to re-weld any part twice ) And welding. *Face*
In fact, once a "reference" resistor with the desired value is obtained, one way to accurately convert the next resistor to the same value is to provide a constant current supply for each resistor and pass a precision resistor The resistor provides voltage to each resistor. One op amp goes to the negative input, and the other goes to the positive input.
When the values of the two resistors are the same, the output of the operational amplifier should tend to zero.
Yes-you have basically described the enlarged Wheatstone bridge. However, you must compensate for the offset of the test op amp by swapping inputs and comparing the results.
Moreover, once you have collected a trim resistor of one value, you can compare the two resistors in series with the resistor you want to trim to 2R. This results in almost exactly matched R and 2R values without the need for a known accurate ohmmeter.
You can use conductive silver paint to reduce resistance, then dry it and scrape it off for calibration.
I once disassembled a UHF tuner and some parts. What I found was the conductive ink mark (carbon) between the various traces, apparently part of its factory alignment process.
In another era, I studied an altitude measurement radar system that uses a very large precision potentiometer (about 8 inches in diameter) to send angle information to an analog computing system. These antennas often wear out because they rotate as the antenna nods (24/7). I separated, it was a miracle of silver ink calibration. The X-acto blade cuts where the resistance is too low, and where the silver ink is too high.
Now, this is my expectation of HAD. My breasts became hairier as soon as I read them, those close-up photos, pfoorrr!
Especially for surface mount resistors, you can try to trim them with acid, just connect them to the tester, then pull them out and neutralize them when they hit the best point. The next step will be to have a complete electrochemical device where you can perform deposition, corrosion and testing, and use the MCU to control everything. Grow your own resistive film.
One thing leads to another. Before you know it, you are building a precision trimmed R-2R trapezoidal hybrid. good idea.
Next, can you tell us how to adjust our potentiometer?
I have heard of this technique before, but there are only a few details, but this article clears all my doubts about this issue. I won’t need high-precision resistors soon, but I think I’ll adopt this idea, which is the so-called proper Hack. As others have said, I want to know how to "re-seal" them to prevent moisture etc. It would be interesting to try some different seals (such as nail polish, enamel, etc.) and check for precise drift over time.
I was surprised that no one mentioned the Wheatstone bridge in the comments.
This article on precision electronics may be a bit outdated, but the information still seems to be relevant to this topic.
There is also some interesting information about random topics scattered throughout the rest of the website.
Thanks-good reading.
In 1968, I saw a tutor dial a resistor with a lighter.
Is it just me or the article does not actually state anywhere that the file reduces or increases the resistance of the part?
It's you. The article pointed out that you can only increase resistance.
All trimming increases resistance because by removing conductive material, it restricts the path through which current flows.
Just think about it-if you connect, for example, a 1k ohm resistor and a 20 ohm resistor in series, and propose a 20 ohm resistor, will it be easier to get accurate results? Will you get better control? In the end, all resistance pairs may be 1025 ohms, but if they are all the same, that should be fine.
It might be right. I was so surprised by the effect of the 1 k / 2 k experiment that I didn't bother with the lower resistance value. But there is a reason. Their metal layer is thicker and should be easier to trim and even more precise. If you have a precision ohmmeter to back it up, please try it and report it?
"Cool odd number" :-D
Don't forget to protect the exposed area after trimming, some varnish can prevent oxidation.
You will not add metal to the file.
Therefore, only one resistance value is needed in the kit, right? Absolutely not. Creating a 1.2kΩ resistor with 1kΩ original resistance will cause trouble"
Do you want to consider this part again? Of course, it sounds like you will only contradict yourself later: P
NVM, my misunderstanding. Less = more resistance?
Wow, there are many comments here, so this might get lost.
If you see this Elliot, I am surprised that I can't find a reference about thick film, especially thick film resistors and trimming.
In my university, I took a course on thick film design. In this practice, you silk printed traces and resistors on the ceramic substrate. What's interesting is that you have different pastes, such as 1k, 10k or 100k paste on the screen and then bake. The traces are made using OR paste.
After baking, you can solder on the trace-unless of course you put it on the dielectric layer of the glass.
Many designs involve the question of whether the wires cross. If necessary, another layer of dielectric and trace paste is required before proceeding.
The resistance design is too low, after baking, you can use a small precision sandblasting machine to trim the resistance value. This is a very interesting process, and research has been conducted on a process that only a few people use today. Ceramic has excellent thermal properties, so you can cool the back of the substrate and still get a good cooling.
On a 1 x 2 inch substrate, we made a 40W Class AB amplifier.
If you want, I can sort out the process and see if I can dig out more information about the project:) Email me!
Ultraviolet curing "blue light" nail polish :-)
Work for me. It also works when you break a very expensive glass lens (don't ask!) and need to re-stick it together when replacing it.
Hold it firmly when gluing, and scrape off the excess once it is set, then it can work normally.
It is also very convenient to adjust the "trimmer", fix the optics and other interesting but esoteric items, such as using a failed LCD panel and Greedbay fished out and then dried EL phosphor or other things peeled panels made of homemade EL sheet.
I am interested in more details about your LCD to EL panel project.
Will corrosion in exposed areas affect resistance over time?
It's not my idea, Jerry is the one.
I did notice that the recent E-ink mod uses uncured epoxy, while EL does require a solid dielectric.
Therefore, why not use a 3D printer to place a line of UV ink mixed with RYB phosphor
And make your own color monitor?
I think the main reason for not doing this is that TFEL has lower power consumption and lower manufacturing costs.
Some monitors have a mean time between failures of 20 years, and as far as I found out, they are still used in B-2.
It is also important to find a real old LCD panel (or an OLED TV that is damaged by some eejit) and get the RGB filter from it.
IIRC these are better than what you usually find, and are 1080P.
You can make a very reliable electronic ink color display from an old monochrome panel, what's the problem.
There is almost no hint: cutting with an X-acto knife for 10 seconds can be "quickly" harvested from a dead OLED TV, the actual filter is in the front plastic plate, and there is also an ITO conductor with rear stripes.
RE: trim the SMT resistance. I used to work in a factory that made equipment that can be tuned to a specific frequency by adjusting the value of the SMT resistor. We performed this operation using a sandblasting drill with tiny (sub-millimeter) nozzles under a high-magnification lens. We are adjusting the target frequency and bandwidth of the complete device, not the target resistance of any one resistor. We adjusted a resistor for frequency and a resistor for bandwidth. A further complication is that sandblasting will put pressure on the resistance, and in order to ensure long-term stability, it must be baked in a 200-degree oven, then checked again and re-adjusted through more sandblasting, and then baked To relieve stress. Then proceed to the final inspection. Resistor adjustment only makes tuning in one direction, so if you overshoot, you must replace the resistor and start over.
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If you plan to give up your job, you might as well take a big step forward.
Maybe most people will try this way, but [Daniel Valuch] obviously really doesn't want to go to work that day.
The idea here is simple: add some current to the resistor to heat the resistor, and put some thermochromic film on the resistor to get a pixel. The next part is not so simple: expand a single pixel into a 32 x 32 matrix.
To make each pixel square, [Daniel] chose to pair 220 ohm SMD resistors to use up to 2,048 components. The choice of using 1,024 bit shift registers made of discrete 74LVC1G175 flip-flops to drive them adds complexity. With the help of Arduino Nano and all other supporting components, there are more than 3,000 devices that may draw 50 amps. These people are stupid or unfortunate and cannot turn on every pixel at the same time. Fortunately, [Daniel] chose to simulate an analog clock here. This leads to other problems, such as handling the cooling lag of the thermochromic film when the pointer is moved, which must be handled in the software.
We have seen other thermochromic displays before, including the most recent
. This display may not be the highest resolution display currently available, but it is big, bold and slightly dangerous, which makes it a big win in our book.
1) Get a huge pet food
2) Place 1024 heating element arrays under it
3) Placed in an environment of 10°C
4) Turn on the pixels at 30C
Congratulations, you can now print bacteria on the petri dish
You can use...life to implement Conway's "Game of Life".
Interesting project, interesting scale! well-done!
If diodes are used instead of resistors, multiplexed drivers can be used.
Well, if you use matrix and multiplexing, you can make it simple. But why should it be simple? Then, you don't need 1024 triggers. There are many ways to do it, and I like simple but highly repetitive patterns. It is very pleasant to see :)
Very interesting project and well built.
The thickness of the PCB looks like a regular 1.6mm. I thought that using an ultra-thin thickness (such as 0.6mm) would greatly reduce the cooling time. Similarly, replacing the super expensive 2512 with a smaller package (0805) will also reduce thermal inertia, because you only need to raise the temperature above the threshold.
By the way, is there room temperature measurement for software current control/compensation?
What is the average power consumption of the display time?
In addition, since it seems that the main purpose is only to display time, why use an orthogonal matrix? Similarly, if there is no quadrant + dial configuration and only two different pointer lengths, it will again greatly reduce the BOM.
0805 is cheaper, but if you want the same size clock and pixels, you need more clocks and pixels, and the difference is that the price is not much. The pixels do not look good either, because black lines appear between the resistors.
The PCB is actually very thick, 3.2mm. The first is for structural reasons, but when designing, I worry that excessive heat leakage will stain the pixels, and the pixel power may be insufficient. It turns out that if you allow transient seconds, 250mW is enough. We go to see it in winter.
At 4.6V, the total power consumption is about 8A. The trigger can be reduced to below 3V by the power supply voltage, which is a good way to regulate winter/summer
Nice project! It would be fun to make a version with IR LED, so the smartphone camera can see it, but not the naked eye. Allow anyone to interact over the phone instead of dedicated Fluke.
Write down good ideas and good progress!
Does anyone know how much heat the resistor actually generates?
Quoting from the linked project page "The pixel is made of 2512 size resistors, each resistor dissipates 250mW (5V/50mA)", all of this is dissipated as heat, unless you increase the power a lot, it's like 99.5% Calories, 0.5% orange light.
I misread the title and thought it was an infrared camera clock, so it can only be read by an infrared camera. Actually more useful
Wow, my AWLAYS wants to do this! Glad to see you did it! ! !
I want to know how much power is needed to use it for the intended use case. Manually calculated from the attached photos, it seems that about 100 pixels (10% of the entire display) are lit, and the author said that greasy things can consume 250W, so I assume that the power consumption of "clock mode" is 200-250W, but I think it depends on whether the pixel needs to run at 100% heat to make the image come out.
I want to know the actual figures.
You can use heating lamps installed on the ceiling of a large building full of people and project the matrix of the heating area, so that if people want to keep warm, they tend to move them to the heated part; if they need to keep cool If you do, you can avoid them. People's ceilings and where they are willing to stand can also be used as clocks. :-) Annoying sound from a speaker matrix or a matrix of wi-fi access points without power but low power, you may have the same effect.
Chicago-Does anyone really know what time it is? (Does anyone really care?)
This is one of the coolest projects on Hackaday. I bet you can increase the resolution by cutting the thermochromic film into 32×32 small and independent square grids while reducing bleeding and input delay.
The technology is incredible and you can easily shrink it to have a nano-pixel display. You can also display the volume by adding resistors to solid blocks of transparent thermochromic material.
If you don’t have a thermochromic material, you can use lard – it is opaque and white at room temperature, it is transparent and brown when heated: D
I added some videos on YouTube
Very very cool. I have done some research on thermochromic materials. Sadly, they are made of highly toxic chemicals, have a rather limited life span, and are very sensitive to ultraviolet light. Thermal cycling will also rapidly degrade the material, which is what we need to do. Within 6 months, the display will fade dramatically.
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