2SC2694 PDF

By adding additional elements to the signal that do not interfere with the normal mono or stereo operation, non-RDS receivers are able to operate when the RDS technology is present on the signal. The baseband signal consists of a number of components. The stereo difference signal is then amplitude modulated as a double sideband suppressed carrier signal at 38 kHz. A pilot tone at 19 kHz half the frequency of the stereo difference signal subcarrier is also transmitted and this is used to enable the receiver demodulator to exactly recreate the 38 kHz subcarrier to decode the stereo difference signal. The stereo difference signal is above the audio hearing range and as a result it does not detract from the normal mono signal.

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By adding additional elements to the signal that do not interfere with the normal mono or stereo operation, non-RDS receivers are able to operate when the RDS technology is present on the signal. The baseband signal consists of a number of components.

The stereo difference signal is then amplitude modulated as a double sideband suppressed carrier signal at 38 kHz. A pilot tone at 19 kHz half the frequency of the stereo difference signal subcarrier is also transmitted and this is used to enable the receiver demodulator to exactly recreate the 38 kHz subcarrier to decode the stereo difference signal. The stereo difference signal is above the audio hearing range and as a result it does not detract from the normal mono signal.

When adding anything new to a transmission, compatibility must be maintained with existing radios. The RDS information is placed above the stereo difference signal on a 57 kHz subcarrier as shown. This happens to be three times the stereo pilot tone frequency. For stereo transmissions the RDS subcarrier is locked onto the pilot tone. It can either be in-phase with the third harmonic of the tone, or as in the case of the BBC it can be in quadrature. The actual subcarrier that is used to carry the information is phase modulated to carry the data.

This gives good immunity to data errors caused by noise whilst still allowing the data to be transmitted at a suitable rate. Combined with the fact that the subcarrier operates at a harmonic of the pilot tone, these facts minimise the possibility of interference to the audio signals. RDS baseband coding The rate at which data is transmitted is This is equal to the frequency of the RDS subcarrier divided by By adopting this data rate the decoding circuits to operate synchronously.

This reduces problems with spurious signals in the decoding circuits. Data is transmitted in groups consisting of four blocks. Each block contains a 16 bit information word and a 10 bit check word as shown. This means that with the data rate of A 10 bit check word may seem to be long. However it is very important in view of the poor signal conditions which can exist.

This can be particularly true for car or portable radios. The check word enables the radio decoder to detect and correct errors. It also provides a method for synchronisation. The data groups are structured so that data can be transmitted as efficiently as possible.

Different stations will want to transmit different types of data at different times. To cater for this there are a there are a total of 16 different group structures. Their applications are outlined in Figure 3. Mixing of different types of data within groups is kept to a minimum. However the coding structure is such that messages which need repeating most frequently normally occupy the same position within groups.

In order that a radio knows how to decode the data correctly, each type of group has to be identified. This function is performed by a four bit code occupying the first four bits in the second block.

Once generated the data is coded onto the subcarrier in a differential format. This allows the data to be decoded correctly whether the signal is inverted or not. When the input data level is "0" the output remains unchanged but when a "1" appears at the input the output changes its state. With the basic signal generated the spectrum has to be carefully limited.

This has to be done to avoid any cross talk in phase locked loop decoders. The power density close to 57 kHz is limited by the encoding each bit as a bi-phase signal. In addition to this the coded data is passed through a low pass filter.

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As VHF FM is intended to provide high quality audio transmissions, background noise needs to be reduced as far as possible. One method of reducing he background noise is to use a scheme called pre-emphasis. Pre-emphasis basics The pre-emphasis and de-emphasis idea can be used on VHF FM because the background noise is more noticeable towards the treble end of the audio spectrum, where it can be heard as a background hiss. To overcome this it is possible to increase the level of the treble frequencies at the transmitter. At the receiver they are correspondingly attenuated to restore the balance. This also has the effect of reducing the treble background hiss which is generated in the receiver. The process of increasing the treble signals is called pre-emphasis, and reducing the in the receiver is called de-emphasis.

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Electronic Components Transistor 2SC2694

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