TDA9178T Philips Semiconductors, TDA9178T Datasheet - Page 8

TDA9178T

Manufacturer Part Number

TDA9178T

Description

YUV one chip picture improvement based on luminance vector-/ colour vector- and spectral processor

Manufacturer

Philips Semiconductors

Datasheet

1.TDA9178T.pdf (36 pages)

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Philips Semiconductors

Smart sharpness controller

The smart sharpness controller (see Fig.16) is a fader

circuit that fades between peaked luminance and

step-improved luminance, controlled by the output of a

step discriminating device known as the step detector.

It also contains a variable coring level stage.

The step detector is basically a differentiator, so both

amplitude of the step and its slope add to the detection

criterion. The smart sharpness controller has four user

controls:

The steepness setting controls the amount of steepness in

the edge-correction processing path.

The peaking setting controls the amount of contour

correction for proper detail enhancement. The envelope

signal generated by the step improvement processor

modulates the peaking setting in order to reduce the

amount of peaking for large sine wave excursions.

With video dependent coring, it is possible to have more

reduction of the peaking in the black parts of a scene than

in the white parts, and therefore automatically reducing the

visibility of the background noise.

The coring setting controls the coring level in the peaking

path for rejection of high-frequency noise.

All four settings facilitate reduction of the impact of the

sharpness features, e.g. for noisy luminance signals.

The colour dependent sharpness circuit increases the

luminance sharpness in saturated red and magenta parts

of the screen. Because of the limited bandwidth of the

colour signals, there is no need to increase the high

frequencies of the colour signals. Instead, the details in the

luminance signal will be enhanced. In this circuit a limited

number of colours are enhanced (red and magenta).

Contrary to normal peaking algorithm, extra gain is applied

for low frequencies (2 MHz at 1f

because the information that is lacking below 2 MHz (at

peaking is still active to enhance the fine details.

1999 Sep 24

OLOUR DEPENDENT SHARPNESS

Steepness control, performed by the I

bits SP5 to SP0

Peaking control, performed by the I

bits PK5 to PK0

Video dependent coring, switched on or switched off by

the I

Coring level control, performed by the I

bits CR5 to CR0.

YUV one chip picture improvement based on luminance

vector-, colour vector- and spectral processor

) is most important. In large coloured parts the normal

C-bus bit VDC

). This is needed,

C-bus DAC:

The smart peaking algorithm has been designed such that

the luminance output amplitude will never exceed 110% of

the luminance input signal amplitude. Therefore the

normal peaking range (12 dB) will be reduced at large

transients, and in case of colour dependent sharpness

there is even more reduction.

However, by setting bit OSP (Overrule Smart Peaking)

one can undo the extra peaking reduction in case of colour

dependant sharpness. It must be emphasized that setting

OSP may lead to unwanted large luminance output

signals, for instance in details in red coloured objects.

The colour transient improvement circuit (see Fig.17)

increases the slope of the colour transients of vertical

objects. Each channel of the CTI circuit basically consists

of two delay cells: an electronic potentiometer and an edge

detector circuit that controls the wiper position of the

potentiometer. Normally the wiper of the potentiometer will

be in position B (mid position), so passing the input

signal B to the output with a single delay. The control

signal is obtained by the signals A and C.

When an edge occurs the value of the control signal will

fade between +1 and 1 and finally will become zero

again. A control signal value of +1 fades the wiper in

position C, passing the two times delayed input signal to

the output. A control signal of 1 fades the wiper in

position A, so an undelayed input signal is passed to the

output. The result is an output signal which has steeper

edges than the input signal. Contrary to other existing

CTI algorithms, the transients remain time correct with

respect to the luminance signal, as the algorithm steepens

edges proportionally, without discontinuity.

A luminance output is available for SCAVEM processing.

This luminance signal is not affected by the spectral

processing functions.

Colour vector processor

The colour processing part contains skin tone correction,

green enhancement and blue stretch. The colour vector

processing is dependent on the amplitude and sign of the

colour difference signals. Therefore, both the polarity and

the nominal amplitude of the colour difference signals are

relevant when using the colour vector processor facility.

CAVEM

OLOUR TRANSIENT IMPROVEMENT

Preliminary speciﬁcation

TDA9178

TDA9178T Philips Semiconductors, TDA9178T Datasheet - Page 8

TDA9178T

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