A communication system, typically wireless and comprising at least one wireless (say) communication network node having a capacity for communicating with at least one additional wireless (say) communication network node at a given center frequency; and at least one external frequency converter, external to the node, operative to cause at least one wireless (say) communication network node, from outside said node, to communicate with at least one additional wireless (say) communication network node, at least on occasion, according to a given e.g. wireless communication protocol, at at least one converted center frequency which differs from the given center frequency, wherein a Channel Compensation Signal (CCS) is employed.

One example may include transmitting data between a client device and a server over a first channel, sending test data on a second channel to identify a transmission rate of the second channel, comparing the transmission rate to a transmission rate threshold, and determining whether to perform bonding of the first channel with the second channel based on the transmission rate of the second channel being greater or less than the transmission rate threshold.

One example may include transmitting data between a client device and a server over a first channel, sending test data on a second channel to identify a transmission rate of the second channel, comparing the transmission rate to a transmission rate threshold, and determining whether to perform bonding of the first channel with the second channel based on the transmission rate of the second channel being greater or less than the transmission rate threshold.

A wireless communication device can include chains of circuitry, with at least one chain being a chain of transmitter circuitry to generate output radio frequency (RF) signals using baseband signals and at least one chain of receiver circuitry configured to receive RF signals. At least one chain can include a plurality of circuit blocks, a circuit block including at least one of oscillator circuitry, clocking circuitry, and phased lock loop (PLL) circuitry. The apparatus can include interconnect circuitry configured to couple one of the plurality of circuit blocks to a respective chain. Other systems, methods and apparatuses are described.

A wireless communication device can include chains of circuitry, with at least one chain being a chain of transmitter circuitry to generate output radio frequency (RF) signals using baseband signals and at least one chain of receiver circuitry configured to receive RF signals. At least one chain can include a plurality of circuit blocks, a circuit block including at least one of oscillator circuitry, clocking circuitry, and phased lock loop (PLL) circuitry. The apparatus can include interconnect circuitry configured to couple one of the plurality of circuit blocks to a respective chain. Other systems, methods and apparatuses are described.

[Problem] To provide a transmission device that has an enhanced redundant structure in which RF signals having a plurality of frequencies are transmitted to continue transmission even in the event of failure and allows simultaneously both improvement in power efficiency and transmission power and high-speed communication. [Solution] A signal generator 1102 generates RF signals 1201 to 1204. Each of the RF signals 1201 and 1202 is simultaneously input to a broadband/multiband power amplifier 1103, and each of the RF signals 1203 and 1204 are simultaneously input to a broadband/multiband power amplifier 1104. Specifically, the RF signals allocated in two different bands 1211 and 1212 are simultaneously input to each of the power amplifiers. The RF signals 1201 to 1204 are amplified by the broadband/multiband power amplifiers 1103 and 1104 and then transmitted via terminals 1105 and 1106.

[Problem] To provide a transmission device that has an enhanced redundant structure in which RF signals having a plurality of frequencies are transmitted to continue transmission even in the event of failure and allows simultaneously both improvement in power efficiency and transmission power and high-speed communication. [Solution] A signal generator 1102 generates RF signals 1201 to 1204. Each of the RF signals 1201 and 1202 is simultaneously input to a broadband/multiband power amplifier 1103, and each of the RF signals 1203 and 1204 are simultaneously input to a broadband/multiband power amplifier 1104. Specifically, the RF signals allocated in two different bands 1211 and 1212 are simultaneously input to each of the power amplifiers. The RF signals 1201 to 1204 are amplified by the broadband/multiband power amplifiers 1103 and 1104 and then transmitted via terminals 1105 and 1106.

In some embodiments, a first computing device detects a loss of a connection to a first source of timing information that the first computing device and a second computing device use to maintain synchronization with a first clock and a second clock. The first computing device receives a second source of timing information from the second computing device. The second source of timing information is also being transmitted to a third computing device. The first computing device uses the second source of timing information to determine a first timestamp and determines a second timestamp from the first clock. The first computing device uses the first timestamp and the second timestamp to adjust a rate of the first clock where the first clock is used to transmit the second source of timing information from the second computing device to the third computing device.

In some embodiments, a first computing device detects a loss of a connection to a first source of timing information that the first computing device and a second computing device use to maintain synchronization with a first clock and a second clock. The first computing device receives a second source of timing information from the second computing device. The second source of timing information is also being transmitted to a third computing device. The first computing device uses the second source of timing information to determine a first timestamp and determines a second timestamp from the first clock. The first computing device uses the first timestamp and the second timestamp to adjust a rate of the first clock where the first clock is used to transmit the second source of timing information from the second computing device to the third computing device.

According to one embodiment, a transmission system may include a plurality of signal processing apparatuses. The signal processing apparatus are connected in series. The signal processing apparatus includes a plurality of signal processors, and a switcher. The signal processors generate an output signal by performing signal processing of an input signal from an earlier-stage signal processing apparatus. The signal processors supply the output signal into which is included an abnormality signal if the input signal does not include the abnormality signal and also the output signal does not satisfy the criteria. The switcher receives a plurality of output signals output from the plurality of signal processors. The switcher supplies an output signal of the plurality of output signals.