Tag Archives: Integrated Circuits

Different IC Packages and Details of Dual In-line Package

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Like transistors and computer chips, integrated circuits (ICs) are encased (hermetically sealed) by packages to keep safe the inner chip’s circuitry from tangible impairment and from any kind of defilement like moisture and dust.

 

For allowing convenient handling and assembly onto printed circuit boards and for keeping safe the devices from any possible damage, integrated circuits are implanted to protective packages. There are a huge number of various types of packages are available. Some of these types have ascertained measurements and endurance which are registered with trade industry associations like Pro Electron and JEDEC. Just one or two manufacturers might make the other types which are proprietary designations. Prior to testing and shipping devices to the customers, integrated circuit packaging is the final assembly method.

 

Other than these, the IC package also aids with redistributing the Input & output of the chips circuitry to a user-friendly component size for use by its end user, along with allowing a structure more congenial to standardization, allowing a fervent heat course away from the chip, providing safeguard from the likelihood of errors because of alpha particles and other various radiations, and providing a composition that more conveniently allows electrical experiment and burn-in by the chip’s maker.

 

The IC package may also be effective to connect more than one IC both directly to one another utilizing standard interconnection technologies like wire bonding, and indirectly utilizing interconnection pathways available on the package such as those used in hybrid IC packages and multi-chip modules (MCMs).

 

The packages also make it simpler to install the ICs in different types of equipment, as every package comprises leads which may be either plugged into corresponding sockets or plugged into mounting frames. Various types of materials are used to manufacture IC packages.

 

Dual in-line package (known as DIP or DIL) is one of the most common among many kinds of IC packages with distinguishable measures, mounting styles, and/or pin-enumerations. In terms of microelectronics, a package of electronic components which has two parallel lines of electrical connecting pins and cased in a rectangular housing is known as dual in-line package. It can be either inserted in a socket or through-hole ascended to a printed circuit board. In 1964, Don Forbes, Bryant Rogers and Rex Rice invented the dual-inline ordination at Fairchild Research & Development. It was during that period, when the limited number of leads obtainable on circular transistor-style packages became a restriction in the application of integrated circuits. Additional signal and power supply leads are needed by the more and more complex circuits (according to the Rent’s rule); in the end, microprocessors and analogous complicated devices needed leads to a greater extent than could be put on a DIP package, which leads to the development of highly dense packages. Moreover, rectangular & square packages made it effortless to route printed-circuit traces underneath the packages.

 

A DIP is generally mentioned as a DIPn, where n is the aggregate number of pins. We can say for example, a DIP14 microcircuit package would consist of two rows of seven vertical leads. Most common DIP packages have four (lowest) to 64 (at most). Numerous digital and analog IC types are attainable in DIP package forms.

Integrated Circuit Designs and Extensions

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Dependability on semiconductor devices by the electronic systems is increasing day-by-day because the integration level is growing quicker than ever and it is necessary to pack more circuitry in the smallest packages. Various circuit components, which are required to complete computer systems such as, capacitors, transistors, resistors, etc, can be installed on an individual silicon die.

 

When a package holds individual silicon (silicon germanium for RF circuits, or gallium arsenide for microwave frequency circuits) that builds up either portion of a bigger electronic circuit or system or an entire electronic system in its own right is called an Integrated Circuit (IC). When a full electronic system is created by the IC, it is generally mentioned as a SoC (System on a Chip). Present-day communication ICs are of SoC designs.

 

MCM (Multichip Module) comprises more than one dies and it is an extension to the IC; we can say for example, circuits and sensors are to be accommodated in an individual package but which is not possible to be set up on an individual die. The MCM was mentioned as a hybrid circuit at the beginning, which consists of multiple ICs and inactive components on a common circuit base that are unified by conductors set up within that base. Complications related to size reduction and signal degradation can be alleviated by implementing MCM.

 

An extension to the IC is the multichip module (MCM), which contains multiple dies; for example, when sensors and circuits are to be housed in a single package but which cannot be fabricated on a single die. Originally referred to as a hybrid circuit, the MCM consists of two or more ICs and passive components on a common circuit base that are interconnected by conductors fabricated within that base. The MCM helps with size reduction problem and helps alleviate signal degradation.

 

Devices are piled vertically on system in a package (SiP), which is an extension to the MCM. Wire bonding to the substrate is usual. An extension to the SiP is the package on a package (PoP).

Dual in-Line Package for Integrated Circuits

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Dual in-line package (known as DIP or DIL) is one of the most common among many kinds of IC packages with distinguishable measures, mounting styles, and/or pin-enumerations. In terms of microelectronics, a package of electronic components which has two parallel lines of electrical connecting pins and cased in a rectangular housing is known as dual in-line package. It can be either inserted in a socket or through-hole ascended to a printed circuit board. In 1964, Don Forbes, Bryant Rogers and Rex Rice invented the dual-inline ordination at Fairchild Research & Development. It was during that period, when the limited number of leads obtainable on circular transistor-style packages became a restriction in the application of integrated circuits. Additional signal and power supply leads are needed by the more and more complex circuits (according to the Rent’s rule); in the end, microprocessors and analogous complicated devices needed leads to a greater extent than could be put on a DIP package, which leads to the development of highly dense packages. Moreover, rectangular & square packages made it effortless to route printed-circuit traces underneath the packages.

 

A DIP is generally mentioned as a DIPn, where n is the aggregate number of pins. We can say for example, a DIP14 microcircuit package would consist of two rows of seven vertical leads. Most common DIP packages have four (lowest) to 64 (at most). Numerous digital and analog IC types are attainable in DIP package forms.

Demonstration of Wafer-Scale Graphene Integrated Circuit Smaller Than a Pinhead For Wireless Devices

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It is alleged by the scientists of IBM research that they have reached a milestone in forming a building block for the subsequent wireless devices. In a paper disclosed in the journal Science, IBM researchist made public the maiden integrated circuit built from wafer-size graphene, and revealed a broadband frequency mixer functioning at frequencies up to 10 gigahertz (10 billion cycles per second).

 

Aimed at wireless communications, this analog integrated circuit based on graphene would make better recent wireless devices and beckons to the possibility for a new set of applications. Among the conventional frequencies of present, transceiver and cell phone signals could be advanced, possibly allowing phones to function where they can’t today while, at much higher frequencies, military and medical personnel could see covert weapons or operate medical imaging without the similar radiation riskiness of X-rays.

 

Graphene is the narrowest electronic material which is composed of a single layer of carbon atoms packed in a honeycomb formation, possesses exceptional electrical, mechanical, optical and thermal characteristics that could make it not so much costly and use less power in mobile electronics like smart phones.

 

In spite of noteworthy scientific advancement in the comprehension of this unprecedented material and the demonstration of high-performance graphene-based devices, the difficulty of combining graphene transistors with other components on an individual chip had not been cognized up to now, majorly because of the deficient adherence of graphene with metals and oxides and the need of dependable fabrication schemes to generate formative circuits and devices.

 

This latest integrated circuit is composed of a graphene transistor and a set of two inductors compactly built-in on a silicon carbide (SiC) wafer, surpasses these design obstacles by advancing wafer-scale fabrication methods that keep up the standard of graphene and, at the same time, make allowance for its consolidation to other elements in an intricate circuitry.

 

In this presentation, thermal annealing of SiC wafers synthesized graphene to comprise stable graphene layers on the surface of SiC. Four layers of metal and two layers of oxide are needed by the fabrication of graphene circuits to make top-gated graphene transistor, interconnects and on-chip inductors.

 

The circuit functions as a broadband frequency mixer, which generates output signals with varied frequencies (aggregate and difference) of the input signals. Mixers are considered as basic elements of various electronic communication systems. This graphene integrated circuit has been presented as capable of frequency mixing up to 10 GHz and fantastic thermal stability up to 125°C

 

The fabrication scheme demonstrated can also be used in other types of graphene materials, including chemical vapor deposited (CVD) graphene films synthesized on metal films, and are also suitable for optical lithography for minimized cost and throughput. In the past, the team has demonstrated stand-alone graphene transistors with a cut-off frequency as high as 100 GHz and 155 GHz for epitaxial and CVD graphene, for a gate length of 240 and 40 nm, respectively.

 

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Integrated Circuit and Transistor Package Types

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Like transistors and computer chips, integrated circuits (ICs) are encased (hermetically sealed) by packages to keep safe the inner chip’s circuitry from tangible impairment and from any kind of defilement like moisture and dust.

 

Other than these, the IC package also aids with redistributing the Input & output of the chips circuitry to a user-friendly component size for use by its end user, along with allowing a structure more congenial to standardization, allowing a fervent heat course away from the chip, providing safeguard from the likelihood of errors because of alpha particles and other various radiations, and providing a composition that more conveniently allows electrical experiment and burn-in by the chip’s maker.

 

The IC package may also be effective to connect more than one IC both directly to one another utilizing standard interconnection technologies like wire bonding, and indirectly utilizing interconnection pathways available on the package such as those used in hybrid IC packages and multi-chip modules (MCMs).

 

The packages also make it simpler to install the ICs in different types of equipment, as every package comprises leads which may be either plugged into corresponding sockets or plugged into mounting frames. Various types of materials are used to manufacture IC packages.

IC Packages

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IC (Integrated Circuit) means an assemblage of electronic components such as resistors, transistors, capacitors, etc. All these are crammed into a very small chip and attached with each other to acquire a common objective.

 

The IC package is what encases the die of integrated circuit and extends it out into a device we can more conveniently attach to. Every external connection on the die is linked via a very small piece of gold wire to a pad or pin on the packaging. The silver, extruding terminals on an IC are the pins. These pins carry out the work to link to different components of a circuit. These are of highest significance to us whereas they are what will go on to connect to the remaining elements and wires in a circuit.

 

Every IC is polarized and each is pin is distinctive in case of both position and operation. For this reason, it is necessary for the package to have some way to impart which pin is which. For most ICs, a dot or a notch (in some cases, both or sometimes anyone of them) designates the first pin. If you can recognize the first pin, the rest of the pin numbers increase according to the sequence as you move counter-clockwise around the chip.

Definition of IC Package Types

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There are numerous varieties of IC packages, each of which has distinctive measures, mounting styles, and/or pin- enumerations. These packages are batched into three major categories: Dual In-line Packages, Grid Arrays and Chip Carriers. Each package, regardless of the category has a body style that scales with pin count. The number of pins determines the physical dimension of the package, the name of the package does not.

 

  1. Dual In-line Packages [DIP], or Dual In-Line [DIL] packages are packages with two rows of leads on two sides of the package. DIP ICs may be through-hole [PDIP or CERDIP] or SMT package [SOJ or SOIC].

 

  1. Quad Flat Packs or Chip Carriers are square packages [or nearly square], with leads on all four sides
    Chip Carriers, as in PLCCs and other variants are strictly Surface Mount Technology (SMT).

 

3.  Grid Arrays are those type packages that have their pins arranged in a grid.
The pin grid may consist of Leads, pads, or solder balls on an area array.
The through hole variant is called a PGA, while the SMT variant might be called LGA or BGA.

Integrated Circuit Packages

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In terms of power consumption, Integrated circuits range from mW (or microwatts) to hundreds of Watts with the number of electrical connections to the next level packaging ranging from eight to more than 1,000. With this wide extent of fascinating packaging to take into account, it is not surprising that any easy generalizations will always find out anomalies.

 

For allowing convenient handling and assembly onto printed circuit boards and for keeping safe the devices from any possible damage, integrated circuits are implanted to protective packages. There are a huge number of various types of packages are available. Some of these types have ascertained measurements and endurances which are registered with trade industry associations like Pro Electron and JEDEC. Just one or two manufacturers might make the other types which are proprietary designations. Prior to testing and shipping devices to the customers, integrated circuit packaging is the final assembly method.

 

Sometimes especially processed integrated circuit dies are made for straight connections to a substrate in the absence of an in-between header or carrier. The IC is attached to a substrate by solder bumps in flip chip systems. In beam-lead technology, the metal coated pads are solidified and expanded for allowing external connections to the circuit.

Integrated Circuit Design

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IC design or Integrated Circuit design is a sub-category of electronic engineering, encircling the specific logic and circuit design techniques needed to design integrated circuits, or ICs. ICs comprise small-scale electronic components such as resistors, transistors, capacitors, etc. fabricated into an electrical grid on a monolithic semiconductor.

 

Digital and analog IC designs are the two wide categories of IC design. Components like microprocessors, FPGAs, different memories (such as: RAM, ROM, and flash) and digital ASICs are produced by digital IC design. Digital design’s main focusing points are logical rightness, ensuring maximum circuit density, and placing circuits to ensure efficient routing of clock and timing signals. Power IC design and RF IC design are the fields in which Analog IC design has specialism. Analog IC design is used in the design of phase locked loops, op-amps, oscillators, linear regulators and active filters. Analog design bothers about the physics of the semiconductor devices like resistance, gain, power dissipation and matching. Integrity of analog signal amplification and filtering is generally critical and for this reason, analog integrated circuits use comparatively bigger area active devices than digital IC designs and commonly not so much dense in circuitry.

Self-healing Electronics is Coming With Extended Life and for Reducing Waste

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A total chip or even the entire device can collapse, if just one very small circuit within an integrated chip stops working or fails. Wouldn’t it be fantastic, if it could repair itself, and repair itself so quickly that the user never realized there was a fault?

 

A self-healing system has been developed by a team of engineers from University of Illinois. It is capable of reinstating electrical conductivity to a faulty circuit in less time than it takes to flicker. Aerospace engineering professor Scott White and materials science and engineering professor Nancy Sottos are the leaders of this team of researchers. They disclosed their results in the journal Advanced Materials.

 

“It simplifies the system,” said chemistry professor Jeffrey Moore, a co-writer of the paper. “Rather than having to build in redundancies or to build in a sensory diagnostics system, this material is designed to take care of the problem itself.”

 

Now-a-days manufacturers are putting as much density onto a chip as possible because electronic devices are evolving to execute more advanced tasks. Because of this kind of density, reliability is compromised. For example, failure stemming from unstable temperature cycles as the device operates or exhausts. The entire device can be shut down because of a failure at any point.

 

“In general there’s not much avenue for manual repair,” Sottos said. “Sometimes you just can’t get to the inside. In a multilayer integrated circuit, there’s no opening it up. Normally you just replace the whole chip. It’s true for a battery too. You can’t pull a battery apart and try to find the source of the failure.”

 

Except some significant applications – like instruments or vehicles for space or military functions where electrical failures cannot be replaced or repaired, most other consumer devices are intended to be replaced with some frequency, adding to electronic waste issues.

 

In the past, a system for self-healing polymer materials was developed by the Illinois team and they opted to adapt their technique for conductive systems. They disseminated very small microcapsules which are tiny as 10 microns in diameter, on top of a gold line acting as a circuit. When a cleft inseminates, the microcapsules break open and release the liquid metal contained inside. To reinstate electrical flow, the liquid metal fills up the gap in the circuit.

 

“What’s really cool about this paper is it’s the first example of taking the microcapsule-based healing approach and applying it to a new function,” White said. “Everything prior to this has been on structural repair. This is on conductivity restoration. It shows the concept translates to other things as well.”

 

Because of the immediate filling of the crack by the liquid metal, the current flow is interrupted for mere microseconds by a failure. It is attested by the researchers that 90% of their samples healed to 99 percent of initial conductivity, even with a small amount of microcapsules.

 

Being localized and autonomous are the other advantages of the self-repairing system. Only those microcapsules are opened, which are intercepted by crack, so repair only takes place at the point of damage. In addition to that, no human interference or diagnostics is needed, which is a blessing for those applications where accessing a cleft for repair is not possible, such as a battery, or searching for the source of a failure is very difficult, such as an air- or spacecraft.