3D Measurement Applications of Integrated Circuits (ICs)

3D Measurement Applications of Integrated Circuits (ICs)

The popularity of 5G as a standard for cellular networks has lead to the miniaturisation of semiconductor devices, which in turn has increased the need for precise inspection and analysis. The latest features of KEYENCE's VK-X Series allow it to perform repeated measurements, location-based programs, and pass/fail inspection through templating. This section introduces technical information and inspection application examples for BGA, wire bonding, contact probes, and similar cases where many inspections are carried out with laser microscopes.

Typical IC Packages

As the integration of ICs has increased, Surface Mount Technology (SMT) has become mainstream. Matrix type (BGA type) packages are also used for highly integrated ICs. LSI is an acronym for Large Scale Integration but is often used as a synonym for Integrated Circuits (IC).

Insertion type package

SIP (Single Inline Package)

These packages are inserted into PCBs. Leads are extended from the long side of the package in a line.

DIP (Dual Inline Package)

These packages are inserted into PCBs. Leads extend downward from both sides of the package.

Surface Mount Technology (SMT) lead type package

SOP (Small Outline Package)

In these SMT packages, leads extend from both sides of the package and the tips of the leads spread out like wings.

SOJ (Small Outline J-leaded Package)

In these SMT packages, leads extend from both sides of the package and tips of the leads are bent inward, as if they cover the package. When viewed from the side, each lead looks like the letter J.

QFP (Quad Flat Package)

In these SMT packages, leads extend from all 4 sides of the package and tips of the leads are spread like wings.

QFJ (Quad Flat J-leaded Package)

In these SMT packages, leads extend from all 4 sides of the package and the tips of the leads are bent inward, as if they cover the package.
When viewed from the side, each lead looks like the letter J.

Surface Mount Technology (SMT) non-lead type package

SON (Small Outline Non-leaded Package)

These SMT packages have no leads. Electrode pads are used as connection terminals. SON are used for two-way types and for small numbers of pins.

QFN (Quad Flat Non-leaded Package)

These SMT packages have no leads. Electrode pads are used as connection terminals. QFN are a four-way type package.

Surface Mount Technology (SMT) matrix type package

BGA (Ball Grid Array)

Solder balls (sphere shaped) are arrayed on the bottom of the package to use as terminals.

PGA (Pin Grid Array)

Pins are arrayed on the bottom of the package to use as terminals.

LGA (Land Grid Array)

Electrode pads (including copper pads) are arrayed on the bottom of the package to use as terminals.

Typical Bonding for IC Chip Mounting

Wire bonding

Wire bonding connects electrodes of semiconductor chips and electric conductors of lead frames or boards with thin wires of gold, aluminium, or copper.

Flip-chip bonding

IC chips are attached directly to PCBs. This method is called FC-BGA (Flip Chip-BGA). Bumps are made at the electrodes of an IC chip and connected to the electrodes of a PCB. Using this method can save space compared to wire bonding.

A
Semiconductor chip
B
Flip (Face down)

Bump Making Methods for Flip-chip Bonding

Solder ball mounting
Solder balls (made in advance) are placed on electrodes and reflowed to make bumps. Higher bumps can be made possible paste printing. Also, standardising the solder ball size prevents final bump height differences.
Paste printing
Solder paste is printed on electrodes and reflowed to make bumps. Throughput is high, but it is difficult to unify the bump height.
Plating
Solder bumps are formed with electroplating. Fine bumps can be made, but throughput is low.

Wire Bonding Flow

  1. Tube shaped capillaries (like an injection needle) with metal wires running through them are used. The wire tip is sparked by high voltage to make it round. The round part is then bonded to the electrode to attach it. This is called Ball Bonding or 1st Bonding. A load from the capillary, ultrasonic waves, and heat from the bonding stage allow the bonding to take place.

  2. The capillary is moved to the 2nd bonding point by pulling the bonding wire in a continuous loop.

  3. When connecting to a lead electrode, no ball is made and the wire is mashed by the capillary. This is called "Stitch Bonding" or "2nd Bonding."

  4. The wire clamper is closed to clip the metal wire, then the capillary is lifted and the wire is cut.

Capillary tip components

1st Bonding
A
Capillary
B
Bonding part
2nd bonding
A
Capillary
B
Bonding part
A
Cone angle
B
Face angle
C
Chamfer angle
D
Chamfer diameter
E
Hole diameter
F
Tip diameter

Wire Bonding Inspection Examples

Wire bonding 3D image
Wire bonding teaching for automatic measurement
Even if the target shifts out of position, the position is corrected automatically, allowing for automatic measurement.
Capillary tip roughness measurement (multiple measurements)
The batch analysis function can be used to optimise inspections.

IC Inspection Examples

Terminal coplanarity measurement
BGA shape measurement
BGA surface roughness comparison
Bump outer diameter and height measurement
Roughness measurement for multiple lines of an IC package
The recommendation function clarifies the roughness parameter that should be used during incoming inspections.
Resist film thickness measurement
Electrode height measurement
Smartphone PCB pattern measurement
Carrier tape shape measurement
Batch analysis enables automatic measurement.

Electrical Inspection Methods

This section introduces typical electrical inspection methods for electronic components. In addition to simply opening or shortcircuiting a component, it is also possible to make current flow through a component.

Probe card

This is a jig used during electric inspection of LSI (large scale integration) chips formed on top of silicon wafers in the wafer inspection process (pre-processing) as part of manufacturing LSI circuits.

Contact probe

This is a jig used during inspection of various electronic components. This inspection targets a wide variety of components including semiconductors, LCD panels, raw PCBs, mounted PCBs, connectors, capacitors, and sensors.

Probe card types

Vertical probe card

With this probe card, a block with a probe affixed vertically is attached to the PCB.

[Advantages]
User-defined probe arrangement (square-block type, suitable for measurement of multiple components)
Easy maintenance (Replacement of a single probe is possible.)
Small scratches
No damage to solder
[Disadvantages]
High price
Difficult to use with aluminium pads
Cantilever probe card

With this probe card, needles made of tungsten or a similar material are fixed in place directly on the PCB.

[Advantages]
Low price
Allows for narrower pitches than vertical probe cards
Easy to use with aluminium pads
[Disadvantages]
Limited pin layout
Maintenance is difficult (Height adjustment and other repairs are required.)
Large scratches

Contact probe structure and tip shapes

A contact probe is constructed from a plunger, barrel, and spring, and is used while embedded in a jig made of resin.

A
Contact probe
a
Barrel
b
Spring
c
Plunger
B
Inspection target
Curve

Used with flexible PCBs and in other situations where damage to electrodes must be avoided.

Needle

Used mainly with PCB pads and similar targets.

Flat and inverted cone

Flat tips are used to contact the surface without damaging the electrodes. Inverted cone tips are used to receive terminals and similar targets.

Triangular pyramid

Used with PCB through-holes and similar targets.

Crown

Used in situations such as contacting multiple points or receiving the leads of mounted components.

Contact Probe Inspection Examples

Probe mark depth measurement
Probe tip wear measurement