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Component Shapes Specific Component Shapes Leaded Component Shapes S tudent Guide SIPLACE V ision (Customer) Component Shapes Edition 12/2008 EN 66 5.3.7.1 ECV Component Shape (Electrolyte Ca pacitor V ertical) JEDEC des…

Component Shapes

Leaded Component Shapes Specific Component Shapes

Student Guide SIPLACE Vision (Customer)

Edition 12/2008 EN Component Shapes

5.3.7 Leaded Component Shapes

In SIPLACE Vision, leaded components are defined as those which have measurable i.e. visible

(narrow) leads. In most cases, the leads are aligned towards the outside.

The CO position and angle are determined from various algorithms such as lead selection, filtering the

recorded image etc.. In a second step, the so-called inspection stage, the system uses gradient

formation to determine the number of leads, lead position and lead grid (pitch) for the CO position

measured in the previous step.

 From SR/MC 603, the position of asymmetrical leads can be optically recognized and then corrected

with "Orientation". The operator gets the notification "component picked up at a wrong angle". In the

case of components such as SOT 23, the additional measuring time required is due to the dynamics

times for the C&P 6/12 head.

Important! This function may NOT be activated for symmetrical lead arrangements! It would lead to

random angle placement errors.

 From SR/MC 702 (SV 4.0.1), SOxx, SOT, DPACK, QFP, Socket, Connector and Nonstandard can

use 'non-specific component features’ for FaceDown recognition.

ECV, SOT, SOXX, SOJ, QFP, PLCC, DPACK, Socket, Connector and Nonstandard now have a lead

width measurement function. This also functions with programmed notches for nonstandard CSs.

Notes for Joint Datasets (ICOS and SIPLACE Vision)

In the following special cases, you may need to program separate group descriptions for ICOS

and SIPLACE Vision:

 In ICOS systems, these bodies are occasionally described as leads when bright component bodies

are used.

 Group and/or lead descriptions were also consciously omitted in this system.

 Components with leads were often trained with only the SIZE measurement mode. In this case,

check whether a general correction for both systems needs to be made in ICOS!

Component Shapes

Specific Component Shapes Leaded Component Shapes

Student Guide SIPLACE Vision (Customer)

Component Shapes Edition 12/2008 EN

5.3.7.1 ECV Component Shape (Electrolyte Capacitor Vertical)

JEDEC description

Lead description

Special features

 The inspection mode is set for Leads. The body dimensions can not be reliably calculated using the

capacitor leads inside the body.

 Conversion from existing CS dataset:

– The body shape Vertical cylinder is NOT recognized from the ICOS data during conversion from

SIPLACE Pro.

– The ECV component is misinterpreted as Moulded CS and needs to be manually edited.

– ECVs with stabilization leads need to be classified as Nonstandard, if they are to be programmed

for SIPLACE Vision.

– Components also need to be programmed as Nonstandard if body recognition for polarity

recognition is programmed.

Joint datasets with ICOS data possible -

Body description: vertical (upright) cylinder.

 The body Z-height determines the length of the nozzle type

to be used in the C&P head.

 The X/Y body dimensions determine the field of vision, the

Region of Interest.

 This component consists of two lead groups, each with one

lead.

 The leads in the two groups must be identical!

 The leads are inside the body surface.

 This component shape has so-called Gullwing leads i.e.

leads with level contact surfaces.

 These leads are as wide as the solder resist contact

surface, on the board connection surface.

 The contact length must be programmed shorter than the

visible lead length, although they appear to have identical

lengths.

 The lead width is significantly narrower than the lead length.

 The lead length must not exceed 50 percent of the body

length.

 No notches may be programmed. The leads are aligned

towards the outside of the body.

Component Shapes

Leaded Component Shapes Specific Component Shapes

Student Guide SIPLACE Vision (Customer)

Edition 12/2008 EN Component Shapes

5.3.7.2 SOD/SOT Component Shape (Small Outline Diode / Small Outline Transistor)

SOT types can be seen as a combination of unusually shaped but frequently used standard component

shapes.

JEDEC description

(see TO 236)

There are two different JEDEC standards for SOT 23, which

results in various different dimension values for this shape.

Body description: rectangular.

 The Z height of the body determines the measurable height

in the CO sensors.

 The X/Y body dimensions determine the field of vision, the

Region of Interest.

 This also determines the starting edge of the Gullwing

leads.

Further component shapes for the SOT class:

SOD 123 (323) (also as SOXX)

Attention when combining with ICOS (for ICOS CHIP or BGA).

SOD 123 (323)

SOD 143 (343)

SOT 25 (also as SOXX)

 This component shape has two (or more) lead groups on

the component.

 The component is recognized by its pins, on the basis of

which the body center and angle can be determined.

When the SOT leads all have the same length, the group

offset along the Y axis must also be identical.

The group offset along the X axis is 0 for both groups.

 The group offset along the X axis is identical for SOD

component shapes, while the group offset along the Y axis

is 0.

SOD