Packaging of vlsi devices
- 1. PACKAGING OF VLSI DEVICES Package Types, Packaging Design Consideration ASHUTOSH SINGH B Tech 4th year (ECE) Hindustan Institute of Technology 0821331024
- 2. TABLE OF CONTENTS 1. INTRODUCTION 2. PACKAGE DESIGN CONSIDERATIONS Number of terminals Electrical design considerations Thermal design consideration Reliability Testability 3. PACKAGE TYPES Through hole packages Surface mounted packages Flip chip packages Chip size packages Multi chip modules 3-D VLSI packaging
- 3. INTRODUCTION Packaging of electronic circuits is the science and the art of establishing interconnections and a suitableoperating environment for predominantly electrical circuits. It supplies the chips with wires to distributesignals and power, removes the heat generated by the circuits, and provides them with physical supportand environmental protection. It plays an important role in determining the performance, cost, andreliability of the system. With the decrease in feature size and increase in the scale of integration, thedelay in on-chip circuitry is now smaller than that introduced by the package. Thus, the ideal packagewould be one that is compact, and should supply the chips with a required number of signal and powerconnections, which have minute capacitance, inductance, and resistance. The package should remove theheat generated by the circuits. Its thermal properties should match well with semiconductor chips toavoid stress-induced cracks and failures. The package should be reliable, and it should cost much lessthan the chips it carries ELECTRONIC PACKAGING REQUIREMENTS
- 4. PACKAGE DESIGN CONSIDERATIONS: PACKAGE PARAMETERS A successful package design will satisfy all given application requirements at an acceptable design,manufacturing, and operating expense. As a rule, application requirements prescribe the number oflogic circuits and/or bits of storage that must be packaged, interconnected, supplied with electric power,kept within a proper temperature range, mechanically supported, and protected against the environment. Thus, IC packages are designed to accomplish the following three basic functions: • Enclose the chip within a protective envelope to protect it from the external environment • Provide electrical connection from chip to circuit board • Dissipate heat generated by the chip by establishing a thermal path from a semiconductor junctionto the external environment To execute these functions, package designers start with a fundamental concept and, using principlesof engineering, material science, and processing technology, create a design that encompasses: 1. Low lead capacitance and inductance 2. Safe stress levels 3. Material compatibility 4. Low thermal resistance 5. Seal integrity 6. High reliability 7. Ease of manufacture 8. Low cost Success in performing the functions outlined depends on the package design configuration, the choiceof encapsulating materials, and the operating conditions. Package design is driven by performance,cost, reliability, and manufacturing considerations. Conflicts between these multiple criteria are common.The design
- 5. process involves many trade-off analyses and the optimization of conflicting requirements. While designing the package for an application, the following parameters are considered: Number of Terminals The total number of terminals at packaging interfaces is a major cost factor. Signal interconnections andterminals constitute the majority of conducting elements. Other conductors supply power and provideground or other reference voltages.The number of terminals supporting a group of circuits is strongly dependent on the function of thisgroup. The smallest pin-out can be obtained with memory ICs because the stream of data can be limitedto a single bit. Exactly the opposite is the case with groups of logic circuits which result from a randompartitioning of a computer. The pin-out requirement is one of the key driving parameters for all levels ofpackaging: chips, chip carriers, cards, modules, cables, and cable connectors. Electrical Design Considerations Electrical performance at the IC package level is of great importance for microwave designs and hasgained considerable attention recently for silicon digital devices due to ever-increasing speed of today’scircuits and their potentially reduced noise margins.As a signal propagates through the package, it isdegraded due to reflections and line resistance. Controlling the resistance and the inductance associatedwith the power and ground distribution paths to combat ground bounce and the simultaneous switchingnoise has now become essential. Controlling the impedance environment of the signal distribution pathin the package to mitigate the reflection-related noise is becoming important. Reflections, in addition,cause an increase in the transition time, and may split the signal into two or more pulses with the potentialof causing erroneous switching in the subsequent circuit and thus malfunction of the system. Controllingthe capacitive coupling between signal traces in the signal distribution path to reduce crosstalk is gainingimportance. Increased speed of the devices demands that package bandwidth be increased to reduceundue distortion of the signal. All these criteria are related through geometric variables, such as conductorcross-section and length, dielectric thickness, and the dielectric constant of the packaging body. Theseproblems are usually handled with transmission line theory.
- 6. Thermal Design Considerations The thermal design objective is to keep the operating junction temperature of a silicon chip low enoughto prevent triggering the temperature-activated failure mechanisms. Thus, the package should provide agood medium for heat transfer from junction to the ambient/heat sink. It is generally recommended tokeep the junction temperature below 150°C to ensure proper electrical performance and to contain thepropensity to fail.Thermal expansion caused by heating up the packaging structure is not uniform — it varies inaccordance with the temperature gradient at any point in time and with the mismatches in the thermalcoefficient of expansion. Mechanical stresses result from these differences and are one of the contributorsto the finite lifetime and the failure rate of any packaging structure.In a simplistic heat transfer model of a packaged chip, the heat is transferred from the chip to thesurface of the package by conduction and from the package surface to the ambient by convection andradiation.Typically, the temperature difference between the case and ambient is small, and henceradiation can be neglected. This model also neglects conduction heat transfer out of the package terminals,which can become significant. A multilayer example, which models the heat transfer from a region inthe silicon device to the ambient, is shown in Fig. 2. Figure 1: Steady-state heat flow and thermal resistance in a multilayer structure (a) path of heat flow; (b)
- 7. The total thermal resistance from the junctionto the ambient is given by: The resulting junction temperature, assuming a power dissipation of Pd, is in analogy with electric circuits. If there are parallel paths for heat flow, the thermal resistances arecombined in exactly the same manner as electrical resistors in parallel. Rθcs, the conductive thermal resistance, is mainly a function of package materials and geometry. Withthe higher power requirements, one must consider the temperature dependence of materials selected indesign. Tj depends on package geometry, package orientation in the application, and the conditions ofthe ambient in the operating environment. The heat sink is responsible for getting rid of the heat of theenvironment by convection and radiation. Because of all the many heat transfer modes occurring in afinned heat sink, the accurate way to obtain the exact thermal resistance of the heat sink would be tomeasure it. However, most heat sink manufacturers today provide information about their extrusionsconcerning the thermal resistance per unit length. Reliability The package should have good thermo-mechanical performance for better reliability. A variety of materialsof widely differing coefficients of thermal expansion (CTEs) are joined to create interfaces. These interfacesare subject to relatively high process temperatures and undergo many temperature cycles in theiruseful life as the device is powered on and off. As a result, residual stresses are created in the interfaces.These stresses cause reliability problems in the packages. Testability Implicit in reliability considerations is the assumption of a flawless product function after its initialassembly — a zero defect manufacturing. Although feasible in principle, it is rarely practiced because ofthe high costs and possible loss of competitive edge due to conservative dimensions, tolerances, materials,and process choices. So, several tests are employed to assess the reliability of the packages.
- 8. PACKAGE TYPES IC packages have been developed over time to meet the requirements of high speed and density. Thehistory of IC package development has been the continuous battle to miniaturize.Figure 3 illustratesthe size and weight reduction of IC packages over time. Figure 2: Packaging trends Figure 3: A generic schematic diagram showing the difference between the surface-mount technology (upper) and through hole technology
- 9. Several packages can be classified as follows: Through Hole Packages Through-the-board hole mounting technology uses precision holes drilled through the board and platedwith copper. This copper plating forms the connections between separate layers. These layers consist ofthin copper sheets stacked together and insulated by epoxy fiber-glass. There are no dedicated via structuresto make connections between wiring levels; through holes serve that purpose. Through holes form asturdy support for the chip carrier and resist thermal and mechanical stresses caused by the variationsin the expansions of components at raised temperatures. Different types (Fig. 5) of through holepackages can be further classified as: Figure 4: Different through mount packages. Dual-in-Line Packages (DIPs) A dual-in-line package is a rectangular package with two rows of pins in its two sides. Here, first the dieis bonded on the lead frame and in the next step, chip I/O and power/ground pads are wire-bonded tothe lead frame, and the package is molded in plastic. DIPs are the workhorse of the high-volume andgeneral-purpose logic products. Quad Flat Packages (QFPs) With the advances in VLSI technology, the lower available pin counts of the rectangular DIP became alimiting factor. With pins spaced 2.4 mm apart on only two sides of the package, the physical size of theDIP has become too great. On the other hand, the physical size of an unpackaged microelectronic circuit(bare die) has been reduced to a few millimeters. As a result, the DIP package has become up to 50 timeslarger than the bare die size itself, thus defeating the objective of shrinking the size of the integratedcircuits. So, one solution is to provide pins all around. In QFPs, pins are provided on all four sides. ThinQFPs are developed to reduce the weight of the package.
- 10. Pin Grid Arrays (PGA) A pin grid array has leads on its entire bottom surface rather than only at its periphery. This way it can offera much larger pin count. It has cavity-up and cavity- down versions. In a cavity-down version, a die is mountedon the same side as the pins facing toward the PC board, and a heat sink can be mounted on its backside toimprove the heat flow. When the cavity and the pins are on the same side, the total number of pins is reducedbecause the area occupied by the cavity is not available for brazed pins. The mounting and wire bonding ofthe dice are also more difficult because of the existence of the pins next to the cavity. High pin count andlarger power dissipation capability of PGAs make them attractive for different types of packaging. Surface-Mounted Packages Surface mounting solves many of the shortcomings of through-the-board mounting. In this technology,a chip carrier is soldered to the pads on the surface of a board without requiring any through holes. Thesmaller component sizes, lack of through holes, and the possibility of mounting chips on both sides ofthe PC board improve the board density. This reduces package parasitic capacitances and inductancesassociated with the package pins and board wiring. Various types of surface-mount packages are availableon the market and can be divided into the following categories. Figure 5: Different surface-mount packages. Small-Outline Packages (SOPs)
- 11. The small-outline package has gull-wing shaped leads. It requires less pin spacing than through-holemountedDIPs and PGAs. SOP packages usually have small lead counts and are used for discrete, analog,and SSI/MSI logic parts. Plastic-leaded Chip Carriers (PLCCs) Plastic-leaded chip carriers, such as gull-wing and J-leaded chip carriers, offer higher pin counts thanSOP. J-leaded chip carriers pack denser and are more suitable for automation than gull-wing leadedcarriers because their leads do not extend beyond the package. Leadless Ceramic Chip Carriers (LCCCs) Leadless ceramic chip carriers take advantage of multilayer ceramic technology. The conductors are leftexposed around the package periphery to provide contacts for surface mounting. Dice in leadless chipcarriers are mounted in cavity-down position, and the back side of the chip faces away from the board,providing a good heat removal path. The ceramic substrate also has a high thermal conductivity. LCCCsare hermetically sealed. Flip-Chip Packages The length of the electrical connections between the chip and the substrate can be minimized by placingsolder bumps on the dice, flipping the chips over, aligning them with the contacts pads on the substrate,and reflowing the solder balls in a furnace to establish the bonding between the chips and the package. This method provides electrical connections with minute parasitic inductance and capacitance. In addition,contact pads are distributed over the entire chip surface. This saves silicon area, increases themaximum I/O and power/ground terminals available with a given die size, and provides more efficientlyrouted signal and power/ground interconnections on the chips. Figure 6: Flip chip packaging and its interconnections.
- 12. Chip Size Packages (CSPs) To combine the advantages of both packaged chip and bare chip in one solution, a variety of CSPs havebeen developed. CSPs can be divided into two categories: the fan-in type and the fan-out type. Fan-in type CSPs are suitable for memory applications that have relatively low pin counts. This typeis further divided into two types, depending on the location of bonding pads on the chip surface; theseare the center pad type and the peripheral pad type. This type of CSP keeps all the solder bumps withinthe chip area by arranging bumps in area array format on the chip surface. The fan-out CSPs are used mainly for logic applications: because of the die size to pin count ratio,the solder bumps cannot be designed within the chip area. Multi-Chip Modules (MCMs) In a multi-chip module, several chips are supported on a single package. Most multi- chip packages aremade of ceramic. By eliminating one level of packaging, the inductance and capacitance of the electricalconnections among the dice are reduced. Usually, the dice are mounted on a multilayer ceramic substratevia solder bumps, and the ceramic substrate offers a dense interconnection network. There are several advantages of multi-chip modules over single-chip carriers. The multi- chip moduleminimizes the chip-to-chip spacing and reduces the inductive and capacitive discontinuities between thechips mounted on the substrate by replacing the die-bump-interconnect-bump-die path. In addition,narrower and shorter wires on the ceramic substrate have much less capacitance and inductance thanthe PC board interconnections.
- 13. Figure 7: A generic schematic diagram of an MCM, showing how bare dice are interconnected to an MCM 3-D VLSI Packaging The driving forces behind the development of three-dimensional packaging technology are similar to themulti-chip module technology, although the requirements for the 3-D technology are more aggressive.These requirements include the need for significant size and weight reductions, higher performance,small delay, higher reliability, and potentially reduced power consumption.