TDA4858 Datasheet, PDF(7/44 Page) NXP Semiconductors – Economy Autosync Deflection Controller (EASDC)

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TDA4858 Datasheet, PDF (7/44 Pages) NXP Semiconductors – Economy Autosync Deflection Controller (EASDC)

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Philips Semiconductors

Economy Autosync Deï¬ection Controller

(EASDC)

Product speciï¬cation

TDA4858

This operation ensures a smooth tuning and avoids fast

changes of horizontal frequency during catching.

In this concept it is not allowed to load HPLL1.

The frequency dependent voltage at this pin is fed

internally to HBUF (pin 27) via a sample-and-hold and

buffer stage. The sample-and-hold stage removes all

disturbances caused by horizontal sync or composite

vertical sync from the buffered voltage. An external

resistor from HBUF to HREF defines the frequency range.

Table 1 Calculation of total spread

spread of:

CHCAP

RHREF

RHREF, RHBUF

Total

for fmax

for fmin

1% Ã (2.3 Ã nS â 1)

8.69%

PLL1 phase detector

The phase detector is a standard type using switched

current sources. It compares the middle of horizontal sync

with a fixed point on the oscillator sawtooth voltage.

The PLL1 loop filter is connected to HPLL1 (pin 26).

Horizontal oscillator

The horizontal oscillator is of the relaxation type and

requires a capacitor of 10 nF at HCAP (pin 29).

For optimum jitter performance the value of 10 nF must not

be changed.

The maximum oscillator frequency is determined by a

resistor from HREF to ground. A resistor from HREF to

HBUF defines the frequency range.

The reference current at HREF also defines the integration

time constant of the vertical sync integration.

Calculation of line frequency range

First the oscillator frequencies fmin and fmax have to be

calculated. This is achieved by adding the spread of the

relevant components to the highest and lowest sync

frequencies fS(min) and fS(max). The oscillator is driven by

the difference of the currents in RHREF and RHBUF. At the

highest oscillator frequency RHBUF does not contribute to

the spread. The spread will increase towards lower

frequencies due to the contribution of RHBUF. It is also

dependent on the ratio nS = f-f-S-S----((-m-m----ai--nx--)-)

The following example is a 31.45 to 64 kHz application:

nS = f-f-S-S----((-m-m----ai--nx--)-) = 3----1-6--.-4-4---5--k---H-k---Hz-----z- = 2.04

Thus the typical frequency range of the oscillator in this

example is:

fmax = fS (max) Ã 1.06 = 67.84 kHz

fmin = f--1S----.-(0-m---8--i-7n---) = 28.93 kHz

The resistors RHREF and RHBUF can be calculated with the

following formulae:

RHREF = -7---4-f--m--Ã--a---kx---H-[--k--z--H--Ã--z---k-]---â¦--- = 1.091 kâ¦

RHBUF = -R----H----R---E----F-n---Ã--â---1-1--.--1---8-----Ã-----n-- = 2.241 kâ¦

Where: n = f-f-m-m----ai-n-x- = 2.35

The spread of fmin increases with the frequency ratio

f-f-S-S----((-m-m----ai--nx--)-)

For higher ratios this spread can be reduced by using

resistors with less tolerances.

1997 Oct 27

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