The crossover network is actually very common in the audio. Just like three examples, the crossover like the speaker box is a passive crossover network; it is like a satellite speaker and super in the subwoofer system. Between the woofer, a crossover network is needed to separate the full-band signal from the two sets of signals to the satellite horn and the subwoofer. In addition, the common electronic crossover system in the concert requires a lot of crossover networks. To process the signals of different frequency bands to speakers of large and small. At this point, I wonder if the reader has a concept of what is a crossover network? If you still don't know, it doesn't matter, please see the description below. The crossover network, as its name suggests, is to pass the signal of a frequency band through the processing of this frequency division network to separate the original signal out of the required frequency band. Take a three-way speaker example for a good bow. The signal from the amplifier to the speaker box is unprocessed. It mixes the signals of the high, medium and low frequency bands and inputs this signal into the box. Signals above 200 Hz and above 2 kHz are given to the tweeter, and a line like this can separate the signal out of the desired frequency band, which is the function of the frequency division network. For the crossover network, if you want to start from the basics, you should talk about the three most primitive filters: one is the high-pass filter, the other is the low-pass filter, and the third is Band-Pass Filter. The high-pass filter is only the signal that is higher than the crossover point in the input signal, and is bypassed and grounded below the crossover point. Similarly, the low-pass filter is the signal below the crossover point. The filter reaches the output; what about the bandpass filter? Of course, the signal between the two crossover points can pass. In fact, readers can also clearly understand that the names of these filters are very deliberate. One is to pass the crossover point, the other is to output below the crossover point, and the last one is the signal between a certain frequency range. . The crossover network is actually very common in the audio. Just like three examples, the crossover like the speaker box is a passive crossover network; it is like a satellite speaker and super in the subwoofer system. Between the woofer, a crossover network is needed to separate the full-band signal from the two sets of signals to the satellite horn and the subwoofer. In addition, the common electronic crossover system in the concert requires a lot of crossover networks. To process the signals of different frequency bands to speakers of large and small. At this point, I wonder if the reader has a concept of what is a crossover network? If you still don't know, it doesn't matter, please see the description below. The crossover network, as its name suggests, is to pass the signal of a frequency band through the processing of this frequency division network to separate the original signal out of the required frequency band. Take a three-way speaker example for a good bow. The signal from the amplifier to the speaker box is unprocessed. It mixes the signals of the high, medium and low frequency bands and inputs this signal into the box. Signals above 200 Hz and above 2 kHz are given to the tweeter, and a line like this can separate the signal out of the desired frequency band, which is the function of the frequency division network. For the crossover network, if you want to start from the basics, you should talk about the three most primitive filters: one is the high-pass filter, the other is the low-pass filter, and the third is Band-Pass Filter. The high-pass filter is only the signal that is higher than the crossover point in the input signal, and is bypassed and grounded below the crossover point. Similarly, the low-pass filter is the signal below the crossover point. The filter reaches the output; what about the bandpass filter? Of course, the signal between the two crossover points can pass. In fact, readers can also clearly understand that the names of these filters are very deliberate. One is to pass the crossover point, the other is to output below the crossover point, and the last one is the signal between a certain frequency range. . The crossover network is actually very common in the audio. Just like three examples, the crossover like the speaker box is a passive crossover network; it is like a satellite speaker and super in the subwoofer system. Between the woofer, a crossover network is needed to separate the full-band signal from the two sets of signals to the satellite horn and the subwoofer. In addition, the common electronic crossover system in the concert requires a lot of crossover networks. To process the signals of different frequency bands to speakers of large and small. At this point, I wonder if the reader has a concept of what is a crossover network? If you still don't know, it doesn't matter, please see the description below. The crossover network, as its name suggests, is to pass the signal of a frequency band through the processing of this frequency division network to separate the original signal out of the required frequency band. Take a three-way speaker example for a good bow. The signal from the amplifier to the speaker box is unprocessed. It mixes the signals of the high, medium and low frequency bands and inputs this signal into the box. Signals above 200 Hz and above 2 kHz are given to the tweeter, and a line like this can separate the signal out of the desired frequency band, which is the function of the frequency division network. For the crossover network, if you want to start from the basics, you should talk about the three most primitive filters: one is the high-pass filter, the other is the low-pass filter, and the third is Band-Pass Filter. The high-pass filter is only the signal that is higher than the crossover point in the input signal, and is bypassed and grounded below the crossover point. Similarly, the low-pass filter is the signal below the crossover point. The filter reaches the output; what about the bandpass filter? Of course, the signal between the two crossover points can pass. In fact, readers can also clearly understand that the names of these filters are very deliberate. One is to pass the crossover point, the other is to output below the crossover point, and the last one is the signal between a certain frequency range. .
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