It's not a circuit diagram, but a block diagram, which means it can't be used to understand the transmitter at the component level.

However it can be used to aid a first level diagnosis of problems, and which circuit board or black box to replace when something fails.

Reading it from left to right, we have:

• Two input sockets, labelled "Input exciter 1,2". An exciter is actually a complete low power transmitter : probably 8 Watts judging by the top display. And the exciters are probably the blue handled boxes below, of which only one is currently in use. This isn't unusual; transmitters are designed for redundancy; if one exciter fails, the other can be started immediately to keep you on air (and this may even be automatic)
• Each exciter feeds a "pi network" of three resistors, into a changeover switch. This provides impedance matching. You may not have got there yet, but radio signals tend to "bounce" off the wrong impedance, and either open or short circuits can reflect signal back into a transmitter, and overheat it. The pi network may also provide attenuation between the exciter and the later stages.
• The changeover switch connects one exciter into the power amplifier, and the other one into a resistor called a "dummy load" to absorb the power frrom the other one. Again, this changeover is probably automatic and its status is probably shown by the LEDs above.
• The first stage of the power amp is a signal splitter (or divider, which probably explains the odd symbol on it!) to feed the same signal to five actual amplifier modules. In other transmitters there may be signals from different studios carrying different channels, but apparently not here.
• Each amplifier has its gain controlled by the "power modulation" control, combined with a signal fed back from the antenna (so that if something goes wrong at the antenna, the reflected power is kept under control). As this transmitter is apparently producing 4.5 kW, presumably each amplifier is contributing 900W. Some transmitters must adjust their power at different times of day, to prevent signals travelling too far at night.
• The five amplifier outputs are combined in a combiner (with the sigma symbol) which has to ensure that if one amplifier fails, the others don't dump their output into it!
• Then a low pass filter (note the middle and top waves are crossed out) to eliminate distortion products from the amps, which would transmit on somebody else's channel)
• and finally the antenna connection.

So it is not a complete transmitter, but a power output stage. And it is likely to be a custom assembly from standard components for a specific power level from a specific station, apparently with just one channel. The block diagram illustrates the specific configuration to help a transmitter engineer who may be called in to service or repair it.

It's not a circuit diagram, but a block diagram, which means it can't be used to understand the transmitter at the component level.

However it can be used to aid a first level diagnosis of problems, and which circuit board or black box to replace when something fails.

Reading it from left to right, we have:

• Two input sockets, labelled "Input exciter 1,2". An exciter is actually a complete low power transmitter : probably 8 Watts judging by the top display. And the exciters are probably the blue handled boxes below, of which only one is currently in use. This isn't unusual; transmitters are designed for redundancy; if one exciter fails, the other can be started immediately to keep you on air (and this may even be automatic)
• Each exciter feeds a "pi network" of three resistors, into a changeover switch. This provides impedance matching. You may not have got there yet, but radio signals tend to "bounce" off the wrong impedance, and either open or short circuits can reflect signal back into a transmitter, and overheat it. The pi network may also provide attenuation between the exciter and the later stages.
• The changeover switch connects one exciter into the power amplifier, and the other one into a resistor called a "dummy load" to absorb the power frrom the other one. Again, this changeover is probably automatic and its status is probably shown by the LEDs above.
• The first stage of the power amp is a signal splitter (or divider, which probably explains the odd symbol on it!) to feed the same signal to five actual amplifier modules. In other transmitters there may be signals from different studios carrying different channels, but apparently not here.
• Each amplifier has its gain controlled by the "power modulation" control, combined with a signal fed back from the antenna (so that if something goes wrong at the antenna, the reflected power is kept under control). As this transmitter is apparently producing 4.5 kW, presumably each amplifier is contributing 900W. Some transmitters must adjust their power at different times of day, to prevent signals travelling too far at night.
• The five amplifier outputs are combined in a combiner (with the sigma symbol) which has to ensure that if one amplifier fails, the others don't dump their output into it!
• Then a low pass filter (note the middle and top waves are crossed out) to eliminate distortion products from the amps, which would transmit on somebody else's channel)
• and finally the antenna connection.

So it is not a complete transmitter, but a power output stage. And it is likely to be a custom assembly from standard components for a specific power level from a specific station, apparently with just one channel.

You may have noticed that most equipment doesn't have a block diagram on the lid : here, because transmitter installations are often custom built, the block diagram illustrates the specific configuration to help a transmitter engineer who may be called in to service or repair it. This ties in with the array of LEDs above, which are likely to indicate the status of each block, to pinpoint the fault fast.

It's not a circuit diagram, but a block diagram, which means it can't be used to understand the transmitter at the component level.

However it can be used to aid a first level diagnosis of problems, and which circuit board or black box to replace when something fails.

Reading it from left to right, we have:

• Two input sockets, labelled "Input exciter 1,2". An exciter is actually a complete low power transmitter : probably 8 Watts judging by the top display. And the exciters are probably the blue handled boxes below, of which only one is currently in use. This isn't unusual; transmitters are designed for redundancy; if one exciter fails, the other can be started immediately to keep you on air (and this may even be automatic)
• Each exciter feeds a "pi network" of three resistors, into a changeover switch. This provides impedance matching. You may not have got there yet, but radio signals tend to "bounce" off the wrong impedance, and either open or short circuits can reflect signal back into a transmitter, and overheat it. The pi network may also provide attenuation between the exciter and the later stages.
• The changeover switch connects one exciter into the power amplifier, and the other one into a resistor called a "dummy load" to absorb the power frrom the other one. Again, this changeover is probably automatic and its status is probably shown by the LEDs above.
• The first stage of the power amp is a signal splitter (or divider, which probably explains the odd symbol on it!) to feed the same signal to five actual amplifier modules. In other transmitters there may be signals from different studios carrying different channels, but apparently not here.
• Each amplifier has its gain controlled by the "power modulation" control, combined with a signal fed back from the antenna (so that if something goes wrong at the antenna, the reflected power is kept under control). As this transmitter is apparently producing 4.5 kW, presumably each amplifier is contributing 900W.
• The five amplifier outputs are combined in a combiner (with the sigma symbol) which has to ensure that if one amplifier fails, the others don't dump their output into it!
• Then a low pass filter (note the middle and top waves are crossed out) to eliminate distortion products from the amps, which would transmit on somebody else's channel)
• and finally the antenna connection.

It's not a circuit diagram, but a block diagram, which means it can't be used to understand the transmitter at the component level.

However it can be used to aid a first level diagnosis of problems, and which circuit board or black box to replace when something fails.

Reading it from left to right, we have:

• Two input sockets, labelled "Input exciter 1,2". An exciter is actually a complete low power transmitter : probably 8 Watts judging by the top display. And the exciters are probably the blue handled boxes below, of which only one is currently in use. This isn't unusual; transmitters are designed for redundancy; if one exciter fails, the other can be started immediately to keep you on air (and this may even be automatic)
• Each exciter feeds a "pi network" of three resistors, into a changeover switch. This provides impedance matching. You may not have got there yet, but radio signals tend to "bounce" off the wrong impedance, and either open or short circuits can reflect signal back into a transmitter, and overheat it. The pi network may also provide attenuation between the exciter and the later stages.
• The changeover switch connects one exciter into the power amplifier, and the other one into a resistor called a "dummy load" to absorb the power frrom the other one. Again, this changeover is probably automatic and its status is probably shown by the LEDs above.
• The first stage of the power amp is a signal splitter (or divider, which probably explains the odd symbol on it!) to feed the same signal to five actual amplifier modules. In other transmitters there may be signals from different studios carrying different channels, but apparently not here.
• Each amplifier has its gain controlled by the "power modulation" control, combined with a signal fed back from the antenna (so that if something goes wrong at the antenna, the reflected power is kept under control). As this transmitter is apparently producing 4.5 kW, presumably each amplifier is contributing 900W. Some transmitters must adjust their power at different times of day, to prevent signals travelling too far at night.
• The five amplifier outputs are combined in a combiner (with the sigma symbol) which has to ensure that if one amplifier fails, the others don't dump their output into it!
• Then a low pass filter (note the middle and top waves are crossed out) to eliminate distortion products from the amps, which would transmit on somebody else's channel)
• and finally the antenna connection.

So it is not a complete transmitter, but a power output stage. And it is likely to be a custom assembly from standard components for a specific power level from a specific station, apparently with just one channel. The block diagram illustrates the specific configuration to help a transmitter engineer who may be called in to service or repair it.