A method for synchronizing radio frequency carrier correction of dynamic radio frequency carriers is provided. The method includes receiving a carrier configuration from a carrier controller to modulate a carrier signal based on the carrier configuration and receiving a time reference and timestamped carrier configuration information from the carrier controller. The timestamped carrier configuration information includes a correlation between a plurality of timestamps and a plurality of carrier attributes. The method also includes synchronizing an internal clock of a RF correction preprocessor to the time reference, and receiving a modulated carrier signal from the RF modem. The method further includes generating a radio frequency correction set including a correction solution for each of a plurality of timeslots based on the timestamped carrier configuration information, and generating a corrected carrier signal based on applying the RF correction set to the modulated carrier signal at a coincident timeslot.

One embodiment relates to a transmitting device, a receiving device, and the like for preventing increases in the number of communication links, power consumption, and circuit layout area. The transmitting device includes a high-speed signal generator, a low-speed signal generator, and a signal superimposing unit. The high-speed signal generator generates a high-speed signal having a limited frequency band. The low-speed signal generator generates a low-speed signal having a frequency lower than the frequency band of the high-speed signal. The signal superimposing unit outputs a superimposed signal of the high-speed signal and the low-speed signal. The receiving device includes a signal separator and a recovery unit. The signal separator separates the received signal into the high-speed signal and the low-speed signal. The recovery unit performs frequency tracking based on the separated low-speed signal and performs phase tracking based on the separated high-speed signal.

A communication unit (400, 500) is described that includes a plurality of cascaded devices that comprise at least one master device and at least one slave device configured in a master-slave arrangement and configured to process at least one of: transmit signals, and receive signals. The at least one of at least one master device and at least one slave device comprises a demodulator circuit (564, 565) configured to: receive a modulated embedded master-slave clock signal (584) that comprises a system clock signal (582) with an embedded frame start signal (580); demodulate the modulated embedded master-slave clock signal (584); and re-create therefrom the system clock signal (588, 585) and the frame start signal (590, 586).

A transmission device of the disclosure includes: a clock signal transmitting circuit that outputs a clock signal onto a clock signal line; a data signal transmitting circuit that outputs a data signal onto a data signal line; and a blanking controller that controls the clock signal transmitting circuit to output a predetermined blanking signal, in place of the clock signal, from the clock signal transmitting circuit to the clock signal line in synchronization with a blanking period of the data signal.

A communication unit (400, 500) is described that includes a plurality of cascaded devices that comprise at least one master device and at least one slave device configured in a master-slave arrangement and configured to process at least one of: transmit signals, and receive signals. The at least one master device includes: a clock generation circuit configured to output a system clock signal; a modulator circuit (562) coupled to the clock generation circuit and configured to receive the system clock signal and a frame start signal and embed the frame start signal into the system clock signal to produce a modulated embedded master-slave clock signal (584); and transmit the modulated embedded master-slave clock signal (584) to the at least one slave device to synchronise the system clock signal and the frame start signal between the at least one master device (510) and at least one slave device (520).

A communication unit (300) is described that includes a plurality of cascaded devices that includes at least one master device and at least one slave device configured in a master-slave arrangement. The at least one master device comprises a modulator circuit (362) configured to: receive a system clock signal and a frame start signal; modulate the system clock signal with the frame start signal to produce a modulated master-slave clock signal (384); and transmit the modulated master-slave clock signal (384) to the at least one slave device. The at least one slave device comprises a demodulator circuit (364) configured to: receive and demodulate the modulated master-slave clock signal (384); and re-create therefrom the system clock signal (388, 385) and the frame start signal (390, 386).

A communication unit (400, 500) is described that includes a plurality of cascaded devices that comprise at least one master device and at least one slave device configured in a master-slave arrangement and configured to process at least one of: transmit signals, and receive signals. The at least one master device includes: a clock generation circuit configured to output a system clock signal; a modulator circuit (562) coupled to the clock generation circuit and configured to receive the system clock signal and a frame start signal and embed the frame start signal into the system clock signal to produce a modulated embedded master-slave clock signal (584); and transmit the modulated embedded master-slave clock signal (584) to the at least one slave device to synchronise the system clock signal and the frame start signal between the at least one master device (510) and at least one slave device (520).

A communication unit (700) is described that includes a plurality of cascaded devices that comprise at least one master device (710) and at least one slave device (720, 723) configured in a master-slave arrangement. The at least one master device (710) and at least one slave device (720, 723) each comprise: an analog-to-digital converter, ADC, (741, 742) configured to use a same re-created system clock signal (788, 790) to align respective sampling instants between each ADC (741, 742). The at least one master device (710) comprises: a clock generation circuit comprising an internally-generated reference phase locked loop circuit (708), configured to output a system clock signal (782, 784); and a modulator circuit (762) coupled to the clock generation circuit and configured to receive and distribute the system clock signal (784). The at least one master device (710) and at least one slave device (720, 723) each comprise: a demodulator circuit (764, 765) configured to receive the distributed system clock signal (784) and re-create therefrom a synchronized system clock signal (788, 790) used by a respective ADC, (741, 742) of each of the the master device (710) and at least one slave device (720).

A communication unit (900) includes a plurality of cascaded devices that comprise at least one master device (910) and at least one slave device (920, 923) configured in a master-slave arrangement. The at least one master device (910) and at least one slave device (920, 923) each include: a demodulator circuit (964, 965) configured to receive a distributed reference clock signal (984) and re-create a system clock signal (988, 990) therefrom; a clock generation circuit comprising an internally-generated reference phase locked loop configured to receive the re-created system clock signal (988, 990) to create a master-slave clock signal; and an analog-to-digital converter, ADC, (941, 942) coupled to the reference phase locked loop and configured to use a same master-slave clock signal (988, 990) to align respective sampling instants between each ADC (941, 942) of the at least one master device (910) and at least one slave device (920, 923).

A communication unit (400, 500) is described that includes a plurality of cascaded devices that comprise at least one master device and at least one slave device configured in a master-slave arrangement and configured to process at least one of: transmit signals, and receive signals. The at least one of at least one master device and at least one slave device comprises a demodulator circuit (564, 565) configured to: receive a modulated embedded master-slave clock signal (584) that comprises a system clock signal (582) with an embedded frame start signal (580); demodulate the modulated embedded master-slave clock signal (584); and re-create therefrom the system clock signal (588, 585) and the frame start signal (590, 586).