JVC 340 SC Horizontal Sweep Failure Detection, Serial Communication, Information, Description

Chapter 2—Functional Description

The three (3) horizontal deflection coils (B, G, and R) are driven in parallel by a single drive circuit and transistor. This is the reason for the inability to remotely control the three (3) raster widths independently. Since the deflection coils are in parallel, it is imperative that they all be connected prior to applying sweep voltage—the interlock circuit ensures this. An output from the Horizontal Power Supply is sent, in series, through all three (3) yoke connectors. This is part of the bias voltage used to operate the base drive circuit for the output section. Thus, if any of the yoke connectors is not connected, the output transistor will not turn on, and no horizontal sweep will be present.

There are two (2) output jumpers on the board, J500 and J501. Their function is to reverse the direction of the current through the horizontal deflection coils for front and rear projection. The output cable shall be connected to J501 for rear projection and J500 for front projection (Jumper Settings, Section 3.9).

Horizontal Sweep Failure Detection

Protection of the CRT from spot burns is accomplished by never allowing the CRT to continue to have beam current when there is no deflection. To this end, the HDB has a sensing circuit that detects when there is a loss of sweep that may cause CRT damage. This circuit senses the horizontal flyback voltage and frequency. By sensing both amplitude and frequency, the projector is able to maintain sweep over the widely varying input conditions allowed and still protect the CRTs from damage. The flyback signal is AC coupled and peak detected, then compared with a reference. As long as the flyback amplitude and frequency are above the minimum allowed, the sweep detection outputs (HSENSBLU, HSENSGRN, and HSENSRED) are pulled high. These signals are sent to the VDB for processing.

Serial Communication

The HDB uses two (2) separate, interrelated serial data communication systems to communicate with the SCB; the IIC bus, and a differential, synchronous data bus. The information transferred over the serial busses is indicated below (I = input to HDB, O = output from HDB). Also noted is whether the information is transferred over the IIC or the serial bus. A change in output data generates an interrupt pulse.

Table 2-6HDB Serial BUS Information