Abstract: Preventing RF signal distortion and signal error producing memory events in a Radio Frequency (RF) power amplifier (RFPA). An element, disposed prior to the Radio Frequency (RF) power amplifier (RFPA) in a signal path of a RF signal input to the RFPA, may enforce a maximum allowable amplitude in a high PAPR instantaneous high peak of the RF signal. An element may also increase or supplement a bias of the Radio Frequency (RF) power amplifier (RFPA) when a high PAPR instantaneous high peak is detected in the RF signal prior to receipt by the RFPA. Additionally, a first element operable detects when an instantaneous output voltage of the Radio Frequency (RF) power amplifier (RFPA) is below a predetermined voltage, and in response, a second element supplies additional current to prevent the output voltage of the RFPA from falling below a predetermined threshold voltage.

Abstract: Approaches for, and articles of manufacturer that embody, dynamic assignment of a MAC address. A remote PHY node may comprise a non-volatile memory and a network element that comprises a CPU. For example, the network element may be a remote PHY device, an Ethernet switch, a Remote MACPHY Device (RMD), a Passive Optical Network (PON) Optical Line Terminal (OLT), a Passive Optical Network (PON) Optical Network Unit (ONU), or a Wi-Fi hot spot router. A communication link exists between the CPU of the network element and the non-volatile memory of the remote PHY node. A module on the network element causes the network element to retrieve, across the communication link, a MAC address from the non-volatile memory of the remote PHY node and adopt the MAC address to identify itself any time that the network element reboots.

Abstract: Determining when to provide a Proactive Grant Service (PGS) scheduling grant. A plurality of PGS grants are issued to a cable modem (CM). The PGS grants that were utilized by the CM are monitored as well as those PGS grants that were not utilized by the CM. A compromise PGS grants pattern for that CM is generated based on the observations of which PGS grants the CM utilized and which PGS grants the CM did not utilize. The compromise PGS grants pattern for that CM optimizes a projected experienced latency and jitter for particular data flows of the CM verses a projected wasted upstream capacity.

Abstract: Estimating a lifespan of a power supply. An internal computerized component periodically obtains a set of measurements read from one or more sensors affixed to a power supply. Such measurements may measure ambient temperature, temperature of an electrolytic capacitor of a power supply, voltage across a power supply, and/or current from the power supply. The internal computerized component analyzes the set of measurements using, at least in part, a weighted set of factors, to obtain an estimate of a lifespan of a power supply. The estimated lifespan may be sent over an optical link or wireless network to an entity monitoring the lifespan of the power supply.

Abstract: Increasing an analog to digital converter (ADC) dynamic range for a communications device. In the communications device, a reference threshold is established for a peak to average power ratio (PAPR) improvement factor for RF signals received by the communications device. A digital to analog converter (DAC) adjustment factor is established for a DAC to account for inaccuracies of a pre-cancellation DAC and fine tuning of an analog gain of received RF signals. A peak amplitude separation element, disposed within the communications device, evaluates an absolute value of a portion of a particular RF signal against the reference threshold. Upon the peak amplitude separation element determining that the portion is smaller than the reference threshold, the element assigns a zero value to a DAC signal current sample; otherwise, the element assigns a quantized value of the sample to the DAC signal current sample, used in adjusting a post-cancellation signal sample.

Abstract: Propagating a downstream (DS) Out-of-Band (OOB) signal at a frequency receivable by a set of legacy set-top boxes (STBs) while supporting enhanced upstream peak data rates. At an input of an amplifier of a physical device, a portion of the DS-OOB signal is tapped to create a tapped DS-OOB signal, which comprises both the DS-OOB signal and all other downstream signals and channels sent from a head-end to a set of customer premises equipment (CPE) via the physical device. The tapped DS-OOB signal is introduced to a band-pass filter that passes the DS-OOB signal and attenuates all other radio frequency (RF) signals to create a filtered DS-OOB signal. The filtered DS-OOB signal is amplified and coupled to a low-pass side of a high-split diplex filter to propagate onto a transmission medium coupled to the CPE. The physical device may be a high-split RF amplifier or a high-split node.

Abstract: Recovering a hardware component, such as a Remote MACPHY node (RMN), a wireless base station, a CATV amplifier, a Wi-Fi hotspot, a microcell, or a PON switch, after a power interruption. A hardware component, upon detecting that input power to the R-PHY device will be imminently interrupted, provides an alarm signal to a central processing unit (CPU) in the R-PHY device. The CPU, in response to receiving the alarm, stores running parameter data for the R-PHY device in a non-volatile memory. The running parameter data is normally obtained through network communications during a boot operation of the R-PHY device. If certain conditions are satisfied, then the R-PHY device recovers from the interruption in input power using the stored running parameter data without obtaining the running parameter data through a normal boot operation, thus shortening the boot time.

Abstract: Increasing a dynamic range of a digital to analog converter (DAC). A signal analysis element is positioned prior to the DAC in a processing path. The element evaluates an instantaneous amplitude of a signal to be applied to the DAC. The DAC is capable of a first full scale value. An additional current source supports a second full scale value of the DAC, which is greater than the first full scale value. Upon the element determining that a condition is not satisfied, the element employs current steering to couple the additional current source to a current sink. However, upon the element determining that the condition is satisfied, the element employs current steering to couple the additional current source to an output of the DAC to support the second full scale value of the DAC.

Abstract: Dynamically adjusting upstream and/or downstream spectrum usage by a Remote PHY node. Cable modem association information for a Remote PHY node is dynamically determined remotely from across a network. The association information identifies which cable modems serviced by the Remote PHY node are physically connected to each of the Remote PHY node ports. Remote PHY node ports are remotely and dynamically assigned to upstream device port and/or downstream device port of a Remote PHY device comprised within the Remote PHY node. Based on the association information, each of the node port of the Remote PHY node may be reassigned to a different upstream device ports and/or downstream device ports of the Remote PHY device. This reassignment may be performed to achieve load balancing of upstream and/or downstream traffic sent between a plurality of cable modems served by the Remote PHY node and a Cable Modem Termination System (CMTS).

Abstract: A communication system that may include a traffic management module and a communication interface module. The communication interface module is arranged to: estimate a status of multiple channels by utilizing hardware channel status estimators, generate filler packets in response to the status of the multiple channels; wherein the filler packets are associated with the multiple channels; send the filler packets to the traffic management module. The traffic management module is arranged to receive multiple input packets that are associated with multiple channels, receive the filler packets; apply a traffic management scheme on the multiple input packets and the filler packets to provide multiple intermediate packets that comprise (a) multiple filler traffic managed packets and (b) multiple non-filler traffic managed packets.

Abstract: Detecting an imminent failure of a power supply. An internal computerized component periodically reads a set of measurements from one or more sensors affixed to a power supply. The internal computerized component and power supply may reside in a variety of different technical contexts. The internal computerized component analyzes the set of measurements using, at least in part, a weighted set of factors, to detect the imminent failure in the power supply. The weighted set of factors may be updated or revised over time and may be specifically tailored for use with specific types of power supplies.

Abstract: Recovering a Remote PHY (R-PHY) device after a power interruption. A hardware component, upon detecting that input power to the R-PHY device will be imminently interrupted, provides an alarm signal to a central processing unit (CPU) in the R-PHY device. The CPU, in response to receiving the alarm, stores running parameter data for the R-PHY device in a non-volatile memory. The running parameter data is normally obtained through network communications during a boot operation of the R-PHY device. If certain conditions are satisfied, then the R-PHY device recovers from the interruption in input power using the stored running parameter data without obtaining the running parameter data through a normal boot operation, thus shortening the boot time.

Abstract: A Remote PHY (R-PHY) node having a specialized Uninterruptible Power Supply (UPS). A R-PHY node comprises a coaxial cable input, one or more Remote PHY (R-PHY) devices, a node power supply designed to supply an entirety of the R-PHY node with power continuously while there is Quasi Square Wave (QSW) AC power supplied to the R-PHY node over the coaxial cable input, and an UPS for supplying power to either the entirety of the R-PHY node or a set of the one or more R-PHY devices when the R-PHY node is not supplied QSW power over the coaxial cable input. The internal UPS adjusts how power is supplied in response to determining that a configurable amount of time has passed since the interruption in QSW power to the R-PHY node.

Abstract: Recovering a Remote PHY (R-PHY) device after a power interruption. A hardware component, upon detecting that input power to the R-PHY device will be imminently interrupted, provides an alarm signal to a central processing unit (CPU) in the R-PHY device. The CPU, in response to receiving the alarm, stores running parameter data for the R-PHY device in a non-volatile memory. The running parameter data is normally obtained through network communications during a boot operation of the R-PHY device. If certain conditions are satisfied, then the R-PHY device recovers from the interruption in input power using the stored running parameter data without obtaining the running parameter data through a normal boot operation, thus shortening the boot time.

Abstract: Detecting an imminent failure of a power supply. An internal computerized component periodically reads a set of measurements from one or more sensors affixed to a power supply. The internal computerized component and power supply may reside in a variety of different technical contexts, such as a Remote PHY node. The internal computerized component analyzes the set of measurements using, at least in part, a weighted set of factors, to detect the imminent failure in the power supply. The weighted set of factors may be updated or revised over time and may be specifically tailored for use with specific types of power supplies.

Abstract: Approaches for compensating for RF imperfections in a system that comprises two or more independent modules. The two or more independent modules may be comprised within a remote PHY node (RPN). RF calibration data is stored in one or more non-volatile mediums for two or more independent modules. Each of the two or more independent modules are electronically coupled in a sequence via a transmission medium. A first independent module digital compensates a RF signal for a set of two or more modules that are coupled together in sequence via the transmission medium. The first independent module may correspond to a remote PHY device (RPD).

Abstract: Configurable adjustment of a power amplifier bias for a power amplifier. The power amplifier may be comprised within a variety of different apparatuses, such as without limitation a remote PHY node, a remote MACPHY node, and a wireless communication device. A processing unit, disposed within an apparatus, instructs an electrical circuit, also disposed within said apparatus, to change an RF signal output power carrying capability of the power amplifier based on a configuration. The configuration may, but need not, be maintained within the apparatus. The change in the RF signal output power carrying capability of the power amplifier causes an adjustment in a power consumption of the power amplifier.

Abstract: Approaches for supporting a RF automatic gain control (AGC) loop. A first module and a second module are coupled together via a single RF transmission cable. The first module might be a Remote PHY Device (RPD). The second module may comprise a power amplifier. Both the first and second module operate on a single automatic gain control (AGC) loop. The first module sends a first signal to the second module over the single RF transmission cable at a first frequency or frequency range. The first module may adjust a gain of the AGC loop based on a second signal sent from the second module to the first module over the single RF transmission cable. The second, counterpropagating signal has a different frequency or frequency range than the first frequency of the first signal, e.g., the second frequency or frequency range may be lower than that of the first frequency.

Abstract: Segregating a node port experiencing ingress. A node that provides a service to a plurality of cable modems may have a plurality of node ports. The node may be a Remote PHY Node or a Remote MACPHY node. In response to detecting that a particular node port of the node is experiencing ingress, the assignment of node ports to upstream device ports are adjusted so that the particular node port experiencing ingress is not be assigned to the same upstream device port as any other node port. In further response to detecting ingress at the particular node port, all node ports assigned to the same upstream device port are caused to be assigned to the same downstream device port. By segregating the node port experiencing the ingress in this manner, the impact of that ingress can be mitigated or eliminated with respect to the other node ports of that node.

Abstract: A method for obtaining and utilizing internet protocol (IP) subnet information, the method may include obtaining by a layer two cable modem termination system (L2 CMTS) information about IP subnets that comprise DHCP leased IP addresses assigned to devices serviced by the L2 CMTS; and maintaining, by the L2 CMTS and based on the information about the IP subnets, a data structure that reflects the IP subnets that comprise the IP addresses that are allocated to the devices serviced by the L2 CMTS.