CN111244607B - Module, system and method for power delivery to remote radio heads - Google Patents

Abstract

The invention relates to a module, a system and a method for power delivery to a remote radio head. A tower system suitable for use in a cellular base station includes a tower, an antenna mounted on the tower, a remote radio head mounted on the tower, and a power supply. A power cable having a power supply conductor and a return conductor is connected between the power source and the remote radio head. A shunt capacitance unit separate from the remote radio head is electrically coupled between the power supply conductor and the return conductor of the power cable.

Description

Module, system and method for power delivery to remote radio heads

The present application is a divisional application of the invention patent application 201680006621.8 entitled "capacitively loaded jumper cable, shunt capacitance unit, and related method for enhanced power transfer to a remote radio head" filed 2016, 1, 27.

Cross reference to related applications

This application claims priority to U.S. patent application serial No.14/487,329 filed on 9, 16, 2014, pursuant to 35u.s.c. § 120 as a continuation-in-part application, which in turn claims priority to U.S. provisional patent application serial No.61/878,821 filed on 9, 17, 2013, the disclosure of each of which is incorporated herein by reference as if set forth in its entirety herein.

Technical Field

The present invention relates generally to remote radio heads, and more particularly to delivering power to remote radio heads located at the top of an antenna tower and/or other locations remote from a power source.

Background

A cellular base station typically comprises, among other things, a radio, a baseband unit and one or more antennas. The radio receives digital information and control signals from the baseband unit and modulates this information into a radio frequency ("RF") signal, which is then transmitted through the antenna. The radio also receives RF signals from the antenna, demodulates them and provides them to the baseband unit. The baseband unit processes the demodulated signal received from the radio into a format suitable for transmission over the backhaul communication system. The baseband unit also processes signals received from the backhaul communication system and provides the processed signals to the radio. A power supply is provided that generates a suitable direct current ("DC") power signal for powering the baseband unit and the radio. The radio is often powered by a (nominal) -48 volt DC power supply.

To increase coverage and signal quality, the antennas in many cellular base stations are located at the top of the tower, which may be, for example, about fifty to two hundred feet tall. In early cellular systems, the power supply, baseband unit and radio were all located in the equipment enclosure at the bottom of the tower to facilitate maintenance, repair and/or later upgrade of the equipment. The coaxial cable(s) are routed from the equipment enclosure to the top of a tower that carries signal transmission between the radio and the antenna. In recent years, however, a transition has occurred where the radio is now typically located at the top of an antenna tower and is referred to as a remote radio head ("RRH"). The use of a remote radio head can significantly improve the quality of cellular data signals transmitted and received by a cellular base station, since the use of a remote radio head can reduce signal transmission losses and noise. In particular, when the coaxial cable is operated along towers that may be 100-200 feet or more, the signal loss that occurs in transmitting signals at cellular frequencies (e.g., 1.8GHz, 3.0GHz, etc.) over the coaxial cable may be significant. Due to this loss of signal power, in systems where the radio is located at the bottom of the tower, the signal-to-noise ratio of the radio frequency signals may be degraded compared to cellular base stations where the remote radio heads are located at the top of the tower near the antenna (note that the signal loss in the wiring connection between the baseband unit located at the bottom of the tower and the remote radio heads located at the top of the tower may be much smaller, since these signals are sent at baseband frequency or as optical signals on a fiber optic cable and then converted to RF frequency at the top of the tower.

Fig. 1 schematically illustrates a conventional cellular base station 10 in which the radio is implemented as a remote radio head. As shown in fig. 1, the cellular base station 10 includes an equipment enclosure 20 and a tower 30, the equipment enclosure 20 is generally located at the base of the tower 30, and the base band unit 22 and the power supply 26 are located within the equipment enclosure 20. The baseband unit 22 may communicate with a backhaul communication system 28. A plurality of remote radio heads 24 and a plurality of antennas 32 (e.g., three sectorized antennas 32) are located at the top of the tower 30. While the use of tower mounted remote radio heads 24 may improve signal quality, it is also desirable to deliver DC power to the top of the tower 30 in order to power the remote radio heads 24.

The fiber optic cable 38 connects the baseband unit 22 to the remote radio head 24 because the fiber optic link can provide greater bandwidth and lower loss transmission. A power cable 36 is also provided for carrying the DC power signal up the tower 30 to the remote radio head 24. The power cable 36 may include a first insulated power supply conductor and a second insulated return conductor. The fiber optic cable 38 and the power cable 36 may be provided together in a hybrid power/fiber optic cable 40 (such a hybrid cable that carries power and data signals up the antenna tower is commonly referred to as a "trunk" cable). The trunk cable 40 may include a plurality of individual power cables, each of which powers a respective one of the remote radio heads 24 located at the top of the antenna tower 30. The trunk cable 40 may include a breakout enclosure 42 at one end (the end located at the top of the tower 30). The individual fibers from the fiber optic cable 38 and the individual conductors of the power cable 36 are separated in a tap line housing 42 and connected to the remote radio heads 24 via respective tap line wires 44 (which may or may not be integral with the trunk cable) that extend between the remote radio heads 24 and the tap line housing 42. The individual tap line wires 44 are commonly referred to as "jumper cables" or "jumpers". Coaxial cables 46 are used to connect each remote radio head 24 to a respective one of the antennas 32.

The DC voltage of the power signal supplied from the power source 26 to the remote radio head 24 via the power cable 36 and the tap line wires 44 may be determined as follows:

V_RRH＝V_PS-V_Drop (1)

wherein V_RRHIs the DC voltage, V, of the power signal delivered to the remote radio head 24_PSIs the DC voltage, V, of the power signal output by the power supply 26_DropIs a reduction in DC voltage that occurs as a result of the DC power signal passing through the power cable 36 and the tap line wires 44 that connect the power source 26 to the remote radio head 24. V_DropIt can be determined according to ohm's law as follows:

V_Drop＝I_RRH*R_Cable (2)

wherein R is_CableIs the cumulative resistance (in ohms) along the power source and return conductors of the power cable 36 and the distribution wires 44 connecting the power source 26 to the remote radio heads 24, and is_RRHIs the average current (in amperes) flowing through the power cable 36 and the tap wire 44 to the remote radio head 24. As is apparent from equation 2, with the current I drawn by the remote radio head 24_RRHIncreasing the voltage drop V along the power cable 36_DropWill also increase. Voltage drop V of equation 2_DropAlso referred to herein as the I R voltage drop.

The power cables 36 and tap line wires 44 employed in cellular base stations typically use copper power and return conductors (or alloys thereof) having physical characteristics familiar to those skilled in the art. An important characteristic of these conductors is their electrical resistance. The resistance of the conductors of the power cable 36 (or tap line conductor 44) is inversely proportional to the diameter of the conductors (assuming a circular shape)A cross-sectional conductor). Therefore, the larger the diameter of the conductor (i.e., the smaller the gauge (gauge) of the conductor), the lower the resistance of the power cable 36. Copper resistance is specified in unit length (typically milliohms (m Ω)/ft); as such, the cumulative resistance R of the power cable 36 and the tap line electrical wires 44_cableAs the length of the cable 36 and the tap line electrical wires 44 increases. Typically, the breakout wires 44 are much shorter than the power cables 36, and thus, the power cables 36 are the primary contributors to the cumulative resistance. Thus, the longer the power cable 36, the voltage drop V_DropThe higher. This effect is well understood and is typically considered by engineers and system architects.

The remote radio heads 24 are typically designed to operate normally if supplied with a DC power signal having a voltage within a specified range. Conventionally, the power supply 26 at the base of the tower 30 would be set to output a constant voltage V_PSOf the DC power signal. Due to V_DropIs the current I supplied to the remote radio head 24_RRHIs transmitted to the remote radio head 24 (see equation 2 above), and thus the voltage V of the power signal delivered to the remote radio head 24_RRHWill follow due to the voltage drop V_DropBy the current I drawn by the remote radio head 24_RRHMay vary. If V_DropBecomes too large, the voltage of the power signal supplied to the remote radio head 24 may be lower than the minimum voltage required to properly power the remote radio head 24.

Disclosure of Invention

Some embodiments of the present invention are directed to jumper cables for cellular base stations. These jumper cables include a cable segment having a power supply conductor and a return conductor enclosed within a cable jacket and electrically insulated from each other, and first and second connectors terminating on opposite first and second ends of the cable segment. These jumper cables also include a shunt capacitance unit (shunt capacitance unit) connected between the power supply conductor and the return conductor, the shunt capacitance unit including at least one capacitor coupled between the power supply conductor and the return conductor.

In some embodiments, at least one of the capacitors may be a non-polar electrolytic capacitor or at least two polar electrolytic capacitors. The at least one capacitor may have a capacitance of at least 400 microfarads. The shunt capacitance unit may be configured to reduce a voltage drop at the remote radio head due to a spike in the direct current power supply signal carried by the jumper cable.

In some embodiments, the shunt capacitance unit may include a housing having first and second apertures through which the cable segments extend, and the at least one capacitor may be mounted within the housing. In such embodiments, the housing may be filled with an epoxy configured to provide environmental protection to the at least one capacitor and the power supply and return conductors. In other embodiments, the shunt capacitance unit may be included in at least one of the first connector and the second connector. In still other embodiments, the shunt capacitance unit may be enclosed within a cable jacket.

In some embodiments, the jumper cable may further include a fuse circuit coupled in series with at least one capacitor between the power supply conductor and the loop conductor. The jumper cable may also include at least one optical fiber within the jacket. Jumper cables may be used at cellular base stations to connect tap housings terminating trunk cables traveling up the antenna tower to remote radio heads.

According to a further embodiment of the present invention, there is provided a method of operating a cellular base station, wherein a direct current ("DC") power signal is output from a power supply and this DC power signal is supplied to a remote radio head mounted remotely from the power supply via a trunk cable and a jumper cable connected in series, the jumper cable including a power supply conductor, a return conductor, and a shunt capacitance unit coupled between the power supply conductor and the return conductor. The voltage level of the DC power signal output from the power supply is adjusted such that the DC power signal delivered to the remote radio head has a substantially constant voltage despite variations in the current level of the DC power signal output from the power supply.

In some embodiments, the power supply may be a programmable power supply, and information may be input to the power supply from which a voltage level of the DC power signal output from the power supply may be determined that will provide the DC power signal at the first end of the power cable with a substantially constant voltage. The method may further include measuring a current level of the DC power signal output from the power supply, wherein the voltage level of the DC power signal output by the power supply is automatically adjusted in response to changes in the measured current level of the DC power signal output from the power supply to become a DC power signal having a substantially constant voltage provided at the first end of the power cable. The method may further include determining a resistance or impedance of the power cable connection between the power source and the shunt capacitance unit by sending an alternating current signal through the power cable connection and through the shunt capacitance unit. The substantially constant voltage may be a voltage that exceeds a nominal power signal voltage of the remote radio head and is less than a maximum power signal voltage of the remote radio head.

According to yet a further embodiment of the present invention, there is provided a shunt capacitance unit for a cellular base station, comprising a housing, a first connector coupled to the housing (the first connector comprising a first power supply conductor and a first loop conductor), and a second connector coupled to the housing (the second connector comprising a second power supply conductor electrically connected to the first power supply conductor and a second loop conductor electrically connected to the first loop conductor). The shunt capacitance units further comprise at least one capacitor electrically coupled between the first power supply conductor and the first loop conductor.

In some embodiments, the shunt capacitance unit may further comprise a fuse circuit coupled in series with the at least one capacitor between the first power supply conductor and the first loop conductor. The at least one capacitor may be a non-polar electrolytic capacitor or at least two polar electrolytic capacitors. The at least one capacitor may have a capacitance of at least 400 microfarads.

Drawings

Fig. 1 is a simplified schematic diagram of a conventional cellular base station with several remote radio heads located at the top of an antenna tower.

Fig. 2A and 2B illustrate the DC voltage and current, respectively, of a DC power signal as a function of time at a remote radio head under steady state conditions.

Fig. 3A is a graph illustrating the current of a DC power signal as a function of time at a remote radio head during a current spike event. Fig. 3B is a graph illustrating how the DC voltage of the power signal at the remote radio head varies over time due to I x R voltage drops caused in response to the current spikes of fig. 3A. Fig. 3C is a graph illustrating the DC voltage of the DC power signal as a function of time at the remote radio head in response to the current spike of fig. 3A when considering I × R and dI/dt voltage drops.

Fig. 4 is a graph illustrating the DC voltage of the DC power signal as a function of time at the remote radio head in response to the current spike of fig. 3A when the shunt capacitance is used to suppress the effect of dI/dt droop, when considering I R and dI/dt voltage drops.

Fig. 5A-5C are circuit diagrams illustrating example locations where shunt capacitance units may be placed along a power cable that conveys a DC power signal up an antenna tower to a remote radio head.

Fig. 6A and 6B are schematic diagrams of a cellular base station illustrating exemplary locations where a shunt capacitance unit may be located at the top of an antenna tower.

Fig. 7 is a schematic diagram illustrating a cellular base station according to a further embodiment of the present invention, which uses a power cable with a shunt capacitance unit built into the power cable.

FIG. 8 is a perspective view of an end of a hybrid power/fiber optic cable that may be used to implement the trunk cable of FIG. 7.

Fig. 9 is a schematic block diagram of a cellular base station according to a further embodiment of the present invention.

Fig. 10 is a schematic diagram illustrating how jumper cables may be used to connect splice enclosures, such as drop boxes or separate enclosures of trunk cables, to remote radio heads.

Fig. 11A and 11B are partially exploded and perspective views, respectively, of a shunt capacitance unit that may be included in the jumper cable of fig. 10, according to some embodiments of the invention.

Fig. 11C is a circuit diagram illustrating how the shunt capacitance unit of the jumper cable of fig. 11A-B is electrically connected between the power supply conductor and the return conductor of the jumper cable.

Fig. 12A and 12B are side views of a capacitively-loaded jumper cable according to further embodiments of the invention.

Figure 13 is a schematic diagram of an inline connector including a shunt capacitance unit according to some embodiments of the present invention.

Figure 14 is a block diagram of a portion of a cellular base station including a jumper cable used to reduce voltage drops and measure resistance of a power cable connection in order to set capacitive loading of an output of a variable power supply powering a remote radio head, according to an embodiment of the invention.

Detailed Description

As described above, when using remote radio heads in cellular base stations, voltage drops occur along the power cables connecting the power supply at the base of the antenna tower to the remote radio heads at the top of the antenna tower. This voltage drop can cause several problems, as explained below.

First, as the current drawn by one of the remote radio heads increases, the voltage drop V across the individual power cable(s) connecting the power supply to the remote radio head_DropAnd likewise increases. Thus, if the voltage drop becomes too large, the voltage of the power signal supplied to the remote radio head may drop below the minimum voltage required to properly power the remote radio head. Thus, for a power cable with fixed-size copper conductors, the voltage drop V_DropThe length of power cable that can be used is effectively limited. While this limitation on the length of the power cable may be overcome by using larger conductors in the power cable, the use of larger conductors may result in increased material and installation costs, increased loads on the tower, and various other disadvantages.

Second, the voltage drop along the power cable also increases the cost of operating the remote radio head due to power losses in delivering the power signal to the remote radio head, and the amount of power loss is a function of the current flowing through the cable. In particular, power lost in delivering power signals to a remote radio head via a power cable (P)_Loss) The following can be calculated:

P_Loss＝V_Drop*I_RRH (3)

wherein V_DropThe average voltage drop along a power cable, in volts. Since antenna towers for cellular base stations can be hundreds of feet tall, and the voltage and current required to power each remote radio head can be quite high (e.g., about 50 volts at about 20 amps), the power loss that can occur along hundreds of feet of wiring can be significant.

Third, another physical characteristic of a power cable that may cause a voltage drop is the inductance per unit length of the conductor of the cable. In particular, the cumulative inductance of the conductors of the power cable may produce a voltage drop, which is expressed as:

V_dI/dtDrop＝L*(dI/dt) (4)

where L is the cumulative inductance of the conductor and dI/dt is the rate of change of current flowing through the conductor with respect to time. In this context, V_{dI/dt Drop}Referred to as the "dI/dt drop". Thus, not only is the voltage drop affected by the change in current (see equation 2), but also how fast the current changes (see equation 4). Examples of situations where the current drawn by a remote radio head may change rapidly ("current spikes") such that the DI/dt voltage drop may affect performance are (1) when multiple handsets are connected simultaneously and require high speed data and (2) when the remote radio head is turned off or on or changes from idle to operational. Although this voltage drop typically lasts only for a period of the order of about 1-20 milliseconds, this period is long enough that a fast current spike can result in a large V_{dI/dt Drop}A value (e.g., up to 5 volts) that may affect the performance of the remote radio head.

According to embodiments of the present invention, various methods are provided that can reduce the effects of the voltage drop described above. These techniques may be used separately or together to improve the performance of cellular base stations that use remote radio heads mounted on top of antenna towers. It will also be appreciated that there are cellular base stations where the remote radio heads and antennas are mounted at locations other than the tower, remote from the baseband equipment and power supply, such as on the roof, on the top of a utility pole, in a subway tunnel, etc. It will be appreciated that the techniques described herein are equally applicable to these "non-tower" remote locations of the remote radio head. Thus, while embodiments of the present invention are described below with reference to tower mounted remote radio heads, it will be appreciated that all of the embodiments described below may be implemented in cellular base stations that place remote radio heads in other locations, such as on the roof, in the top of a utility pole and tunnel, or other locations remote from power and baseband equipment.

For example, in some embodiments, a shunt capacitance unit, such as a capacitor, may be provided between two conductors of a power cable for providing a DC power signal to a remote radio head. The shunt capacitance unit may reduce the dI/dt voltage drop that would otherwise occur in response to current spikes. In some embodiments, the shunt capacitance units may be integrated into a power or mains cable comprising separate power cables for providing power to remote radio heads on the antenna tower. In other embodiments, the shunt capacitance unit may be incorporated into a jumper cable that connects the remote radio head to a splice or tap housing of the power cable. In still other embodiments, the shunt capacitance unit may be incorporated into an inline connector that may be connected to, for example, a jumper cable. In some embodiments, the shunt capacitance unit may be sized based on, for example, the length of the power cable and the resistance per unit length of the power supply and return conductors included in the power cable.

In some embodiments, the shunt capacitance unit may be used with a programmable power supply configured to (1) sense the current drawn by the remote radio head (or another suitable parameter), and (2) regulate the voltage of the power signal output by the power supply to substantially maintain the voltage of the power signal supplied to the remote radio head at or near a desired value. This desired voltage value may be, for example, a value close to the maximum voltage of the power signal that may be input to the remote radio head. In some embodiments, the programmable power supply may be based on power cablingThe resistance and the current of the power signal output from the power supply set the voltage of the DC power signal output by the power supply so that the voltage of the power signal at the top of the tower will be substantially maintained at a desired level. For example, the resistance of the power cable may be input to the power source, calculated based on information input to the power source, or measured. As the current drawn by the remote radio head varies, the programmable power supply can adjust the voltage of its output power signal to a voltage level that will deliver a power signal to the remote radio head that is at or near the maximum voltage of the power signal that can be input to the remote radio head. As shown in equation (5) below, which extends equation (3), power loss varies with the square of the current drawn by the remote radio head. By increasing the voltage of the signal delivered to the remote radio head, the current I of the power signal_RRHCorrespondingly, power losses are reduced. Since a typical remote radio head may require about one kilowatt of power and may operate 24 hours per day, 7 days per week, and since a large number of remote radio heads (e.g., three to twelve) may be provided at each cellular base station, power savings may be significant.

P_Loss＝V_Drop*I_RRH＝(I_RRH*R_Cable)*I_RRH＝I_RRH ²*R_Cable (5)

While the programmable power supply discussed above will alter the voltage of its output power signal in response to the current drawn by the remote radio head, the voltage change in the output power signal may lag behind the change in current. Therefore, even in the case of using a programmable power supply, dI/dt loss is still caused, which may deteriorate the performance of the remote radio head. Thus, in some embodiments, programmable supply and shunt capacitance units may be used to counter the negative effects of both I R and dI/dt voltage drops.

It is known in the art to use capacitors to help maintain the voltage level of a signal during current spikes. Also, commercially available remote radio heads may include an internal bulk capacitance across the input terminals for the power leads, which is used to reduce ripple and noise on the DC power signal lines. However, it is not believed that the recognition of the effect of the dI/dt voltage drop on the performance of the remote radio head is well understood, nor is it believed that the benefits that can result from providing the ability to provide a variable amount of shunt capacitance, for example, between the leads of a power cable for the remote radio head, where the shunt capacitance unit can be sized based on the length of the power cable, the cumulative resistance of the conductors of the power cable, and/or various other factors such that the shunt capacitance unit can be designed to overcome the problem of the dI/dt voltage drop. According to some embodiments, the shunt capacitance unit may be integrated directly into the power cable, into the jumper cable, or connected to an inline connector of the jumper cable.

Embodiments of the present invention will now be discussed in more detail with reference to fig. 2-14. In which exemplary embodiments of the invention are shown.

As noted above, according to embodiments of the present invention, power cables, jumper cables, and inline connectors may be provided that have relatively large shunt capacitance units, which may be used to maintain the voltage of a power signal delivered to a remote radio head at or above a desired minimum level during current spikes. The effect of including a large shunt capacitance on the voltage of the power signal delivered to the remote radio head is illustrated in fig. 2-4.

Fig. 2A and 2B illustrate power signals received at a remote radio head under steady state conditions. In particular, fig. 2A is a graph plotting the DC voltage (V) of a power signal delivered to a remote radio head as a function of time when the remote radio head is operating in a steady state condition_RRH) And fig. 2B is a graph plotting the current (I) of the power signal drawn by the remote radio head as a function of time under such steady state conditions_RRH) The figure (a). As shown in FIGS. 2A-2B, under such steady state conditions, the voltage V_RRHAnd current I_RRHCan be kept constant.

Fig. 3A-3C illustrate how the voltage and current of a power signal at a remote radio head changes in response to current spikes. In particular, FIG. 3A illustrates that power information may be present when the current demand of a remote radio head increasesCurrent spikes occurring in the sign. As shown in fig. 3A, the current spike may be approximated as a step function. Such current spikes may occur, for example, if multiple carriers require (key up) transmission at the same time. Suppose that a power supply is outputting a power signal V having a constant voltage_PSFIG. 3B illustrates the voltage V of the power signal at the remote radio head with increased current draw_RRHThe influence of (c). Specifically, as shown in FIG. 3B, the increased current draw will result in a voltage V of the power signal at the remote radio head based on ohm's law_RRHIs reduced. FIG. 3C is a graph illustrating how dI/dt drop further affects the voltage V of the power signal supplied to the remote radio head_RRH. As shown in FIG. 3C, the dI/dt voltage drop may result in a voltage V_RRHIs reduced and it gradually reverts to the new steady state voltage applied. The disconnection in fig. 3C indicates a voltage level at which the power signal may not be sufficient to properly power the remote radio head. As shown in fig. 3C, in some cases, the dI/dt voltage drop may be sufficient to cause the remote radio head to temporarily malfunction due to an insufficient voltage level of the power signal.

FIG. 4 is a graph illustrating how a shunt capacitance unit may be used to suppress the effect of the dI/dt voltage drop shown in FIG. 3C. As shown in FIG. 4, the shunt capacitance unit can suppress current spike vs. voltage V_RRHThe influence of (c). The voltage spike of fig. 3C is mostly dissipated by the shunt capacitance unit, so that the voltage level V is_RRHDoes not fall below a disconnection indicating an operational problem with the remote radio head. The shunt capacitance unit effectively acts as an auxiliary power supply, which helps maintain the voltage by discharging the stored charge during a current spike event. Once a steady state condition is reached, the shunt capacitance unit can be recharged, which can be used to suppress the effects of the next current spike. By including a shunt capacitance unit, undesirable events (e.g., remote radio head shut down) that may be caused by undesirable voltage spikes may be reduced or prevented.

Fig. 5A-5C are circuit diagrams illustrating exemplary locations where shunt capacitance units 48 may be placed along the power cables 36 that carry power signals up the antenna tower 30 to the remote radio heads 24. In each of fig. 5A-5C, the power supply 26 is connected to the remote radio head 24 mounted on the antenna tower 30 via a power cable 36. As shown in each of fig. 5A-5C, the power cable 36 for each remote radio head 24 may include a power supply conductor 36-1 and a return conductor 36-2. Conductors 36-1, 36-2 may each be modeled as a plurality of inductors disposed in series. In the embodiment of fig. 5A, a shunt capacitance unit 48 is interposed between the power supply conductor 36-1 and the return conductor 36-2 near the power supply 26 (i.e., at the base of the tower 30). Alternatively, FIG. 5B shows that the shunt capacitance unit 48 may be inserted as a series of shunt capacitors 48 inserted along different points of the power supply conductor 36-1 and the return conductor 36-2. Fig. 5C shows that a shunt capacitance unit 48 may be inserted between the power supply conductor 36-1 and the return conductor 36-2 near the top of the tower 30 or near the remote radio head 24 near the top. While fig. 5A-5C show a single power cable 36 connecting the power supply 26 to the remote radio heads 24 to provide a simplified example, it will be appreciated that more generally, the end of the power cable 36 at the top of the antenna tower 30 is terminated to a splice enclosure or includes an integrated breakout enclosure, and a jumper cable is connected between this enclosure and each remote radio head 24, the jumper cable carrying power and data signals between the enclosure and each remote radio head 24.

In some embodiments (such as the embodiment shown in fig. 5C), the shunt capacitance unit 48 is placed very close to the remote radio head 24. Fig. 6A and 6B identify two locations near the remote radio head 24 that may be considered accessible and may be used as locations for the shunt capacitance unit 48. As shown in fig. 6A, the tower 30 may include an interface housing 50 (sometimes referred to as a "drop box") positioned adjacent the remote radio head 24 near the top of the tower 30. Splice enclosure 50 typically includes bus bars, fiber tap units, etc., and has externally accessible connectors. The remote radio head 24 is connected to the tap box 50 via the tap wire 44. The power supply 26 is connected to a tap box 50 via a power cable 36 (which may be a hybrid power/fiber optic trunk cable 40). As shown in fig. 6A, one exemplary location for shunt capacitance unit 48 is inside of tap box 50 or at tap box 50, with tap box 50 at a relatively long distance up tower 100. In fig. 6B, a cellular base station is shown having the same components as the cellular base station of fig. 6A, except that a shunt capacitance unit 48 is connected at the input of the remote radio head 24. In the embodiment of fig. 6B, the shunt capacitance unit 48 may be included in an inline connector module, for example. Fig. 13 illustrates such an inline connector module according to an embodiment of the present invention. The exemplary locations of the shunt capacitance units 48 illustrated in fig. 6A and 6B are relatively accessible to a technician.

Fig. 7 is a schematic block diagram illustrating a cellular base station 100 including a shunt capacitance unit in a power cable 136 supplying a DC power signal from a power supply 26 to a plurality of remote radio heads 24 according to a further embodiment of the present invention. In the example of fig. 7, a total of three remote radio heads 24 are mounted on an antenna tower 30. The power cable 136 includes three pairs of insulated copper conductors 136A-136C (i.e., three individual power cables 136A-136C are included in the composite power cable 136) that are used to convey DC power signals from the power source 26 to the respective remote radio heads 24. Each pair of insulated copper conductors 136A-136C includes a power supply conductor 136-1 and a return conductor 136-2. The power supply 26 includes three output terminals 27A-27C. One end of each of the respective power cables 136A-136C is connected to a respective one of the outputs 27A-27C on the power supply 26, while the other end of each of the respective power cables 136A-136C is connected to a respective one of the remote radio heads 24. The three outputs 27A-27C on the power supply 26 are independent of each other and may each deliver a power signal that meets the power requirements of a respective one of the remote radio heads 24. Thus, through output 27, power supply 26 may provide three separate power signals having voltage and current characteristics suitable to meet the instantaneous power requirements of each remote radio head 24.

Fig. 8 is a schematic diagram illustrating a trunk cable assembly 200 that may be used, for example, to implement the power cable 136 (and fiber optic cable 38) of fig. 7. The trunk cable assembly 200 of fig. 8 includes a hybrid power/fiber optic cable 210, a first drop barrel 230, and a second drop barrel 250. The hybrid power/fiber optic cable 210 has nine individual power cables 212 (see the callout in fig. 8, which depicts three individual power cables 212) that can be stranded together to form a composite power cable 218, and a fiber optic cable 220 that includes thirty-six optical fibers 222. The fiber optic cable 220 may include any suitable conventional design fiber optic cable, with or without a jacket. The composite power cable 218 and the fiber optic cable 220 may be enclosed in a jacket 224. While one example hybrid power/fiber optic cable 210 is shown in fig. 8, it will be appreciated that any conventional hybrid power/fiber optic cable may be used, and that the cable may have more or fewer power cables and/or optical fibers. An exemplary hybrid power/fiber optic cable is the HTC-24 SM-1206-.

The first dispensing cartridge 230 includes a body 232 and a cover 236. The main body 232 includes a hollow stem 234 at one end that receives the hybrid power/fiber optic cable 210 and a cylindrical receptacle (receptacle) at an opposite end. A cap 236 is mounted on the cylindrical container to form a take-off spool 230 having an open interior. The hybrid power/fiber optic cable 210 enters the body 232 through the rod 234. The composite power cable 218 is broken down into nine individual power cables 212 within the first breakout drum 230. Each individual power cable 212 includes a power supply conductor 214 and a return conductor 216. Nine individual power cables 212 are routed through respective receptacles 238 in the cover 236 where they are received by respective protective conduits 240 (such as nylon conduits that may be sufficiently stiff to resist damage from birds). Thus, each individual power cable 212 extends from the first take-off spool 230 within a respective protective conduit 240. The optical fibers 222 are maintained as a single group and routed through a specific receptacle 238 on the cover 236 where they are inserted as a group into the conduit 242. Thus, the first breakout drum 230 serves to singulate the nine power cables 212 of the composite power cable 218 into individual power cables 212, which can be run to the respective remote radio heads 24 while passing through all of the optical fibers 222 to the individual breakout drums 250.

As shown in the inset of fig. 8, a plurality of shunt capacitance units in the form of ceramic capacitors 248 are provided within the first shunt cylinder 230. Each capacitor 248 is connected between the power supply conductor 214 and the return conductor 216 of a respective one of the independent power cables 212. The tap barrel 230 may include a plurality of receptacles, each receptacle receiving one of the capacitors 248. Each individual power cable may be physically and electrically connected to these outlets. For low frequency signals, such as DC power signals, the shunt capacitors 248 appear as open circuits, and thus the DC power signals carried on each individual power cable 212 will reach the remote radio head 24 through the respective shunt capacitor 248. However, as discussed above, the shunt capacitor 248 may be similar to the auxiliary power supply to reduce the magnitude of the dI/dt voltage drop on the DC power signal during periods when the current carried by the single power cable 212 spikes in response to increased current demand at the remote radio head 24.

As noted above, the optical fiber 222 passes through the first take-off spool 230 as a single unit in the conduit 242 that is connected to the second take-off spool 250. In the second drop barrel 250, thirty-six optical fibers 222 are separated into 9 optical fiber subunits 252. The optical fiber subunits 252 are each protected within a respective conduit 254. The second tap barrel 250 may be similar to the first tap barrel 230 and thus will not be discussed in detail. However, the second shunt cartridge 250 does not include the shunt capacitor 248.

As known to those skilled in the art, commercially available remote radio heads may have a capacitance across the leads that receive a power cable that powers the remote radio head. However, this capacitance is typically small and may not be sufficient to suppress the dI/dt voltage drop. By providing a power cable (such as the hybrid power/fiber optic cable assembly 200 of fig. 8) with a shunt capacitor 248 integrated into each individual power cable 212, it is possible to ensure that sufficient shunt capacitance is provided in each case. For example, as discussed above, since the I × R based voltage drop increases linearly with the length of the power cable, the longer the power cable, the more significant the voltage drop becomes. Thus, longer power cables are more likely to experience the situation shown in fig. 3C above, where the combination of I ar voltage drop and dI/dt voltage drop may cause the voltage of the power signal to temporarily fall below some minimum required voltage level, thereby interrupting operation of the remote radio head. By implementing a shunt capacitance within a power cable that may be sold at a known length, the size of the shunt capacitance may be suitably pre-adjusted to provide a sufficient amount of capacitance without providing additional capacitance that may increase the cost, size, and/or weight of the power cable.

Furthermore, by implementing a shunt capacitance within the power cable (and more specifically within the drop wire housing of the power cable), it is possible to have a shunt capacitance that is appropriately sized at installation. For example, in some embodiments, the shunt capacitance may be a plug-in or screw-in capacitor connected across the conductors of each power cable, such that an appropriately sized capacitor may be installed in the tap reel based on the particular needs of the cellular base station. Furthermore, since the tap-off drums can be opened, defective or damaged capacitors can be replaced if necessary after installation.

Those skilled in the art will recognize that the shunt capacitance used in embodiments of the present invention may be provided in any number of forms. For example, the shunt capacitance unit may be in the form of a separate component (such as one or more capacitors), or in the form of other physical structures (such as parallel conductors separated by an air gap that may function like capacitors). The amount of shunt capacitance provided may vary depending on a number of factors including, for example, the length of the conductor and the diameter of the conductor. In general, in some embodiments, the amount of shunt capacitance may be on the order of hundreds, thousands, tens of thousands, or hundreds of thousands of microfarads.

Benefits that may result from using shunt capacitance in the manner described herein may include the following. From a system perspective, the conductors of the power cable for the remote radio head do not need to be oversized or over-designed to compensate for the large dI/dt voltage drop; thus, longer conductor runs (run) using less conductor material are possible. The use of less conductor material also allows for lighter power cable assemblies, which may also be advantageous because the increased current demand at the top of the tower is a rapidly growing problem. Furthermore, existing tower architectures can be retrofitted with this approach, which has minimal impact on installed hardware if the dI/dt voltage drop occurs as a problem. In particular, embodiments of the present invention may allow for a variable amount of required capacitance based on, for example, conductor length, while also allowing for the ability to retrofit existing towers, power cables, or remote radio head architectures.

According to further embodiments of the present invention, a power cable including a shunt capacitance may be used in a cellular base station that uses a programmable power supply to reduce I R voltage drop by maintaining the voltage of the power signal at the remote radio heads at or near the maximum voltage for the power signal specified for each remote radio head. An example of such an embodiment will now be described with reference to fig. 9.

In particular, fig. 9 is a schematic block diagram of a cellular base station 300 according to an embodiment of the present invention. As shown in fig. 3, the cellular base station 300 includes an equipment enclosure 20 and a tower 30. The base band unit 22, the first power source 326 and the second power source 328 are located within the equipment enclosure 20. A plurality of remote radio heads 24 and a plurality of antennas 32 are mounted on the tower 30.

Each remote radio head 24 receives digital information (data) and control signals from the baseband unit 22 via the fiber optic cable 38. Typically, the fiber optic cable 38 will include a plurality of optical fibers, with two (or more) optical fibers being provided for each remote radio head 24. Each remote radio head 24 modulates the data signals received over its respective "uplink" optical fiber to radio frequency ("RF") signals at the appropriate cellular frequency and then transmits through an antenna 32. Each remote radio head 24 also receives RF signals from the antenna 32, demodulates the signals, and provides the demodulated signals to the baseband unit 22 via a corresponding "downlink" optical fiber included in the fiber optic cable 38. The baseband unit 22 processes the demodulated signals received from the remote radio heads 24 and forwards the processed signals to the backhaul communication system 28. The baseband unit 22 also processes signals received from the backhaul communication system 28 and provides these signals to the remote radio heads 24. In general, the baseband unit 22 and the remote radio head 24 each include optical-to-electrical and electrical-to-optical converters that couple digital information and control signals to and from the fiber optic cable 38.

The first power supply 326 generates a direct current ("DC") power signal. The second power source 328 is a DC-DC converter that accepts as input the DC power signal output by the first power source 326 and outputs a DC power signal having a different voltage. A power cable 336 is connected to the output of the second power source 328 and travels up the tower 30. The power cable 336 may be a composite power cable that includes a plurality of individual power cables, i.e., a separate power cable for each remote radio head 24. In some embodiments, the fiber optic cable 38 and the power cable 336 may be implemented together as a hybrid power/fiber optic cable 340, which may be implemented, for example, using the hybrid power/fiber optic cable assembly 200 of fig. 8. Although the first power source 326 and the second power source 328 are shown as separate power source units in the embodiment of fig. 9, it will be appreciated that in other embodiments, the two power sources 326, 328 may be combined into a single power source unit.

Power supply 328 is a programmable power supply that receives an input DC power signal from power supply 326 and outputs a DC power signal to each individual power cable within power cables 336. The voltage of the DC power signal output by the power supply 328 may vary in response to variations in the current of the DC power signal drawn from the power supply 328 by the remote radio head 24 connected to each individual power cable. The voltage of the DC power signal output by the power supply 328 may be set such that the voltage of the DC power signal at the distal end of each individual one of the power cables 336 (i.e., the end adjacent to the remote radio head 24) is maintained at or near the maximum specified voltage of the power signal for the remote radio head 24. This may reduce power losses associated with providing the DC power signal to the remote radio heads 24, because, for a given power level, higher voltages for the DC power signal correspond to lower currents, and lower current values result in reduced power losses. In some embodiments, the programmable power supply 328 may be designed to maintain the voltage of the DC power signal at or near the maximum operating voltage for the power signal that may be supplied to the remote radio head 24.

In some embodiments, by drawing D from the power source based on (1)Current of C power signal (note, V according to equations 1 and 2_RRHIs I_RRHFunction of) and (2) resistance R of the power cable_CableTo set the voltage level of the power signal output by power source 328, the voltage of the DC power signal (i.e., V) at the distal end of a separate one of power cables 336 may be set_RRH) Maintained at or near the predetermined value. A programmable power supply according to embodiments of the present invention may be configured to measure, estimate, calculate, or receive both values. U.S. patent application serial No.14/321,897 ("the' 897 application"), filed on 2.7.2014, describes various programmable power supplies that may be used to implement programmable power supply 328. The' 897 application is incorporated by reference herein in its entirety, and thus further description of the entirety of the implementation of these programmable power supplies will be omitted. It is noted that the resistance or impedance of the power cable may be used to set the voltage level of the power signal output by the power source 328, and references herein to "resistance" of the power cable are intended to cover resistance and/or impedance. In other embodiments, a feedback loop may be used to control the voltage of the DC power signal output by the DC power supply such that the voltage of the DC power signal at the distal end of the power cable connecting the power supply 328 and the remote radio head 24 is maintained at a desired level. The use of such a feedback loop is also discussed in the' 897 application.

The use of such a programmable power supply can reduce both power loss and I R voltage drop, because supplying a power signal having a voltage maintained near the maximum acceptable value to each remote radio head reduces the average current of the power signal, thereby reducing the I R voltage drop. Furthermore, cellular base stations according to embodiments of the present invention may also employ shunt capacitance on each individual power cable in the manner described above with reference to FIGS. 2-8 to reduce the effect of the dI/dt voltage drop.

According to further embodiments of the invention, the shunt capacitance unit may be incorporated into a jumper cable connected to a tap housing of a trunk cable, or a separate connector housing connected to a remote radio head, or may be included in an inline connector unit, for example, connected directly to such a jumper cable. In some cases, this approach may have advantages over including a shunt capacitance unit in the trunk cable.

As discussed above, trunk cables are often used to transmit power from a power source and data signals from a baseband unit located at the bottom of an antenna tower adjacent a cellular base station to a splice enclosure (or other drop enclosure or drum) mounted near the top of the antenna tower. Typically, the trunk cable includes a plurality of pairs of power conductors and a plurality of pairs of optical fibers, wherein each pair of power conductors is provided to carry power signals to a respective one of the remote radio heads mounted atop the antenna tower, and each pair of optical fibers is provided to carry uplink and downlink traffic to the respective one of the remote radio heads. These power conductor and fiber pairs are terminated into connectors provided in the splice enclosure. A separate jumper cable may be connected between the respective connector of the joint housing and the respective remote radio head to complete the connection between each remote radio head and the power supply and the baseband equipment of the antenna tower base. In some cases, separate power and fiber optic jumper cables are provided, while in other cases, a composite jumper cable that includes both optical fibers and power conductors (separately connectorized) may be used to connect each remote radio head to the splice enclosure.

The jumper cable is much shorter in length than the trunk cable because the splice enclosure is typically located just a few feet from the remote radio head, while the trunk cable travels tens or hundreds of feet up the antenna tower. Furthermore, the jumper cable comprises much fewer components. For example, an electrical jumper cable may include a 6 foot cable with two insulated conductors and connectors at either end. In contrast, for an antenna tower with nine remote radio heads (which is an increasingly common configuration), the trunk cable may be 250 feet long, including eighteen insulated conductors, and also including eighteen optical fibers, along with connectors for each power conductor and optical fiber. As such, trunk cables are typically much more expensive than jumper cables.

If shunt capacitance is implemented in the trunk cable, the retrofit facility may require replacement of the existing trunk cable, which may be very expensive both in cost of the trunk cable and in cost associated with replacement of the trunk cable in terms of man-hours, equipment rental, etc. As noted above, shunt capacitance units according to embodiments of the present invention may also suffer from faults, especially when the power wiring on the cellular antenna may suffer from lightning strikes and/or other voltage surges. When such a failure occurs, it may also be necessary to replace the cable wiring or the housing in which the shunt capacitance unit is contained. This can be very expensive when the shunt capacitance unit is contained in the trunk cable or its tap housing. While, from a capital cost perspective, replacing the shunt capacitance unit contained in the splice enclosure may be less expensive, opening the splice enclosure at the top of the cellular tower is generally discouraged for a variety of reasons (such as safety, environmental sealing issues, etc.). Thus, when placing the shunt capacitance unit in the trunk cable, the trunk cable shunt housing and/or splice housing may have various advantages, such as positioning the shunt capacitance unit a short distance from an associated remote radio head, and adjusting the size of the capacitance based on the length of the trunk cable, which may also have various disadvantages.

Providing jumper cables with associated shunt capacitance units may provide a more efficient and cost effective way to retrofit existing cellular base stations to include shunt capacitance units. As noted above, jumper cables are much less expensive than trunk cables, and therefore, even if multiple jumper cables may need to be replaced (because separate jumper cables connect each remote radio head to either the splice enclosure or the breakout enclosure of the trunk cable), they can be replaced at a lower cost. Moreover, jumper cables can be easily replaced by technicians because they are designed to be connected and disconnected, and jumper cable replacement does not cause environmental sealing problems as with opening splice enclosures. Since any labor performed at the top of the antenna tower is expensive, the ease with which modifications can be performed by using jumper cables with associated shunt capacitance units may represent a significant advantage. The advantages provided by jumper cables with associated shunt capacitance units for retrofit applications also apply in the case of capacitors of the shunt capacitance units burning out and having to be replaced.

In addition, positioning the shunt capacitance unit in the jumper cable may also place the shunt capacitance unit closer to the remote radio head. As discussed above, this may provide improved performance. Moreover, maintaining an inventory of jumper cables with shunt capacitance units may be more efficient than maintaining an inventory of trunk cables with such shunt capacitance units.

A jumper cable with an associated shunt capacitance unit according to an embodiment of the invention will now be discussed with reference to fig. 10-12 and 14.

Figure 10 is a schematic diagram illustrating how a splice enclosure (such as a drop box of a trunk cable or a separate enclosure) can be connected to a remote radio head using a jumper cable with an associated shunt capacitance unit according to an embodiment of the invention. As shown in fig. 10, a trunk cable 410 is terminated to a splice enclosure 420, for example, at the top of an antenna tower (not shown). A jumper cable 430-1 connects the splice enclosure 420 to the remote radio head 440. The jumper cable 430-1 includes a cable segment 431. Cable segment 431 may include a power supply conductor 432 and a return conductor 433 (see fig. 11A) that are electrically insulated from each other. In some embodiments, the power supply conductor 432 and the return conductor 433 may each comprise 8 gauge to 14 gauge copper or copper alloy wire. The wires may be solid or may be twisted. Litz wires may be preferred in some embodiments because they may increase the flexibility of the jumper cable 430-1. In some embodiments, two twisted gauge 10 wires may be twisted together to form the power and/or return conductors 432, 433. The use of two smaller wires twisted together to form the power and/or return conductors 432, 433 may further enhance the flexibility of the jumper cable 430-1.

A protective sheath 434 may enclose the power and return conductors 432, 433. First and second connectors 435, 436 are terminated to either end of cable segment 431. The first connector 435 is configured to connect to a mating connector 422 on the engagement housing 420 and the second connector 436 is configured to connect to a mating connector 442 of the remote radio head 440. Typically, the connector 422 on the engagement housing 420 and the connector 442 on the remote radio head 440 are identical such that either of the connectors 435 and 436 may be connected to either of the connectors 422, 442. The jumper cable 430-1 may include a power cable that includes only the power and return conductors 432, 433, or may instead be a hybrid fiber power cable that includes the power and return conductors 432, 433 along with two or more optical fibers. The jumper cable 430-1 may include an associated shunt capacitance unit 438, which may be implemented at various locations. The configuration and operation of the shunt capacitance unit 438 will be described in more detail below with reference to fig. 11A-12B.

In some embodiments, the shunt capacitance unit 438 may be implemented on the jumper cable 430-1 as a sealing unit 500 inserted along the cable segment 431. Fig. 11A and 11B are a broken line perspective view and a partially exploded perspective view, respectively, of an exemplary embodiment of a sealing unit 500 that may be used to implement shunt capacitance unit 438. As shown in fig. 11A-11B, the sealing unit 500 may have a housing 510 including housing members 520, 530. Each housing member 520, 530 includes a respective cable aperture 522, 532 that allows cable segment 431 to pass through housing 510. The housing members 520, 530 may be formed of, for example, a thermoplastic material or anodized aluminum. In the embodiment of FIGS. 11A-11B, the shunt capacitance is implemented using a pair of electrolytic capacitors 540-1, 540-2 connected in series between the power supply conductor 432 and the return conductor 433. The capacitors 540 may have a cylindrical shape and may be physically positioned such that a longitudinal axis of each capacitor 540 extends along a longitudinal axis of the cable segment 431. In an example embodiment, the capacitor(s) 540 may have a total capacitance between 400 and 2500 microfarads. The housing 510 may include a pair of openings 524, 534. A first one 524 of the openings may be used to inject an environmental sealing element (such as epoxy) into the interior of the housing 510, and a second one 534 of the openings may allow air to escape during the epoxy filling operation. An epoxy (not shown) may be injected as a gel and may fill the interior of the housing 510. The epoxy may dry to a hardened, air and water impermeable solid that fills the shell 510 when exposed to air. In some embodiments, a lid (not shown) may be placed over the openings 524, 534, while in other embodiments, the openings 524, 534 may remain uncovered.

The capacitor 540 may include, for example, a non-polar electrolytic capacitor. The use of the non-polar capacitor 540 may allow the jumper cable 430-1 to be installed in either direction between the splice enclosure 420 and the remote radio head 440. In other words, if the jumper cable 430-1 is implemented using the non-polar capacitor 540, the connector 435 of the jumper cable 430-1 may be paired with the mating connector 422 on the engagement housing 420 or the mating connector 442 of the remote radio head 440, and the jumper cable 430-1 will operate normally. Conversely, if a polar capacitor is used instead, the connector 435 will always need to be connected to the mating connector 422 on the engagement housing 420 to prevent damage to the capacitor. As the skilled artisan may not recognize, if the jumper cable 430-1 is installed in the wrong orientation, the capacitor may be damaged or destroyed, and the use of the non-polar capacitor 540 may prevent installation errors and damage to the jumper cable. In some embodiments, at least two polar electrolytic capacitors may be used instead of a non-polar electrolytic capacitor.

The electrolytic capacitor 540 (or other capacitor used to implement the shunt capacitance) may fail for a variety of reasons. For example, voltage surges caused by, for example, lightning strikes, may damage these capacitors 540. Further, electrolytic capacitors may have manufacturing defects that may not be recognized during factory testing, but may result in premature failure of the capacitor in the field. Jumper cables according to some embodiments of the invention may have circuitry designed to ensure or at least increase the likelihood of: if one of the capacitors 540 fails during use, the capacitor 540 will appear as an open circuit between the power and ground conductors 432, 433. As long as such an open circuit is present, the jumper cable 430-1 will continue to perform like a normal jumper cable that does not include the shunt capacitance unit 500. If the capacitor 540 fails to open, the jumper cable 430-1 may be more susceptible to the dI/dt voltage drop, but otherwise the jumper cable 430-1 will continue to operate and the failure of the capacitor 540 will not result in a general link failure.

To ensure that the capacitor 540 will present an open circuit between the power and ground conductors 432, 433 in the event of a failure thereof, a fuse circuit 550 may be provided to create an open circuit in the event of a failure of the capacitor 540. The fuse circuit 550 may be internal to the capacitor 540 or may be a separate circuit external to the capacitor 540. In some embodiments, the fuse circuit 550 may be implemented using a fuse 552 inserted along a shunt path between the power supply and return conductors 432, 433. If the capacitor 540 fails in a manner that causes a short circuit between the power supply and return conductors 432, 433, the fuse 552 will "blow" (i.e., create an open circuit) as a result of the increased current across the shunt path. The fuse 552 may be designed to conduct a relatively small current that will flow through the capacitor 540 in response to the dI/dt voltage drop, but the fuse 552 will blow in response to a much larger current that will pass if the capacitor 540 fails and creates a short circuit between the power supply and return conductors 432, 433. The fuse circuit 550 may be any suitable circuit that creates an open circuit along the shunt capacitance path in the event that the capacitor 540 fails in such a way as to create a short circuit between the power supply and return conductors 432, 433.

Fig. 11C is a circuit diagram illustrating how the shunt capacitance unit 500 is interposed between the power supply and return conductors 432, 433. As shown in FIG. 11C, capacitors 540-1 and 540-2 are connected in series between power supply conductor 432 and return conductor 433. Fuse circuit 550 is located in series between capacitors 540-1 and 540-2. In other embodiments, the fuse circuit 550 may be located, for example, between the power supply conductor and the first capacitor 540-1 or between the return conductor 433 and the second capacitor 540-2.

Fig. 12A and 12B are side views of capacitively-loaded jumper cables 430-2 and 430-3 according to further embodiments of the invention. As discussed above with reference to fig. 10, 11A, and 11B, in some embodiments, the shunt capacitance unit 438 of the jumper cable 430-1 may be implemented as a sealing unit 500 inserted along the cable segment 431. As schematically shown in fig. 12A, in other embodiments, a jumper cable 430-2 may be provided, wherein a shunt capacitance unit 438 may be implemented within a cable jacket 434 to eliminate the need for a housing 510. In such an embodiment, the cable jacket 434 may provide environmental protection to the shunt capacitance unit 438. In yet a further embodiment, as schematically illustrated in fig. 12B, a jumper cable 430-3 may be provided, wherein the shunt capacitance unit 438 may be implemented within one of the connectors 435, 436 of the jumper cable 430-3, again eliminating the need for a separate housing 510. In such an embodiment, connectors 435, 436 may provide environmental protection for shunt capacitance unit 438. In the jumper cables 430-2 and 430-3 of fig. 12A and 12B, the shunt capacitance unit 438 may have the circuit configuration shown in fig. 11C.

It will also be appreciated that in still further embodiments, the shunt capacitance unit may be implemented as a separate unit that may be connected, for example, between the splice enclosure 420 and a conventional jumper cable or between the remote radio head 440 and a conventional jumper cable. By way of example, fig. 13 illustrates how individual shunt capacitance units may be provided in the form of an inline connector module 600, which inline connector module 600 may connect between a conventional jumper cable 430 and either the splice enclosure 420 or the remote radio head 440. As shown in fig. 13, the inline connector module 600 includes a housing 610 and first and second connectors 620, 622. The connector 620 may be configured to connect to one of the connectors 435, 436 of the conventional jumper cable 430, and the connector 622 may be configured to mate with a connector of the connector housing 420 or the remote radio head 440. The power and ground conductors 632, 633 may be provided within the inline connector module 600, and a shunt capacitance unit 640 including one or more capacitors may be provided, and the shunt capacitance unit 640 optionally includes a fuse circuit connected in series along a shunt path between the power and ground conductors 632, 633. The power and ground conductors 632, 633 and the capacitors and fuse circuits of the shunt capacitance unit 640 may be electrically arranged with respect to each other as shown in the circuit diagram of fig. 11C.

As discussed above with reference to fig. 9, in some embodiments, the shunt capacitance unit may be used in a cellular base station employing a programmable power supply that is used to reduce I x R voltage drop by maintaining the voltage of the power signal at the remote radio heads at or near the maximum value of the power signal specified for each remote radio head. It will be appreciated that the shunt capacitance unit may be implemented in the trunk cable, in the jumper cable, or using a separate unit as discussed in the various embodiments above.

As discussed in detail in the above-referenced' 897 application, in some embodiments, the programmable power supply may be configured to measure, estimate, calculate, or receive the resistance of a power wiring connection (this connection typically includes a trunk cable and a jumper cable) interposed between the power supply and the remote radio head. According to a further embodiment of the invention, a shunt capacitance unit may be used to measure the impedance of the power wiring connection.

In particular, fig. 14 is a schematic block diagram illustrating how a shunt capacitance unit according to an embodiment of the invention may be used to facilitate measuring the resistance of power cabling between a power source and, for example, a remote radio head. As shown in fig. 14, a programmable power supply 700 can be provided that delivers DC power to the remote radio head 760 via power supply and return conductors 751, 752 of a power wiring connection 750. The power wiring connection 750 may include one or more cables. For example, the power wiring connection 750 may include power supply portions of a trunk cable and a jumper cable connected in series between the programmable power supply 700 and the remote radio head 760. As shown in fig. 14, a shunt capacitance unit 753 is provided along a power wiring connection 750 adjacent to the remote radio head 760. The shunt capacitance unit 753 may be implemented, for example, in a jumper cable that connects the power supply and return conductors of the trunk cable to the remote radio head 760.

The programmable power supply 700 includes a DC power generator 710 that provides a DC power signal used to power the remote radio head 760. The programmable power supply 700 also includes a pulse generator 720 configured to generate an alternating current ("AC") control signal, which may also be sent to the power wiring connection 750. This AC signal may be a voltage pulse of, for example, 100Hz to 100 kHz. The frequency of the voltage pulses may be chosen such that the voltage pulses will pass through the capacitor of the shunt capacitance unit 753. The frequency of the voltage pulses may also be selected to be lower than the RF data signal transmitted by the remote radio head 760 to reduce or minimize any potential interference between the voltage pulses and the RF data signal.

Since the shunt capacitance unit 753 will appear as a short circuit to the voltage pulse, the voltage pulse will not pass to the remote radio head 760, but will instead flow through the shunt capacitance unit 753 and back to the programmable power supply 700. Ohm's law may then be used to determine the resistance of power cable 750 based on the current/voltage characteristics of the voltage pulses received at programmable power supply 700. The programmable power supply 700 may include control circuitry 740 that is used to measure the voltage and/or current levels of the loop voltage pulses, and control logic 730 that calculates the resistance of the power wiring connection 750 based thereon.

Thus, in the embodiment of fig. 14, as long as the shunt capacitance unit is functioning properly, it can be used as a bypass path for voltage pulses to allow the programmable power supply 700 to measure the resistance of the power cable 750 and dynamically change the output of the power supply 700 based thereon. Also, if the capacitor in the shunt capacitance unit 753 fails, the voltage pulse will no longer be received at the power supply 700 because the shunt capacitance unit 753 will fail as an open circuit. When this occurs, the power supply 700 may be configured to sound an alarm so that the shunt capacitance unit may be replaced.

The present invention has been described with reference to the accompanying drawings, in which certain embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth and described herein; these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout the specification and drawings. It will also be appreciated that the embodiments disclosed above can be combined in any manner and/or combination to provide many additional embodiments. For example, the shunt capacitance units described herein may be used in any of the example embodiments disclosed in the aforementioned' 897 application.

It will be understood that, although the terms first, second, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another. For example, a first element could be termed a second element, and, similarly, a second element could be termed a first element, without departing from the scope of the present invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description above is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in this disclosure, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will also be understood that when an element (e.g., a device, circuit, etc.) is referred to as being "connected" or "coupled" to another element, it can be directly connected or coupled to the other element or intervening elements may be present. In contrast, when an element is referred to as being "directly connected" or "directly coupled" to another element, there are no intervening elements present.

It will be further understood that the terms "comprises" and/or "comprising," when used herein, specify the presence of stated features, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, operations, elements, components, and/or groups thereof.

In the drawings and specification, there have been disclosed typical embodiments of the invention and, although specific terms are employed, they are used in a generic and descriptive sense only and not for purposes of limitation, the scope of the invention being set forth in the following claims.

Claims (36)

1. A method of power delivery, the method comprising:

supplying a Direct Current (DC) power signal from a power source to a remote radio head mounted remotely from the power source over a power cabling connection, the power cabling connection including a power supply conductor and a return conductor, the power cabling connection including a shunt capacitance unit coupled between the power supply conductor and the return conductor, the shunt capacitance unit including at least one capacitor coupled between the power supply conductor and the return conductor;

sending an alternating current, AC, control signal onto the power cable connection;

receiving the AC control signal after the AC control signal passes through the shunt capacitance unit; and

determining a resistance or impedance of the power cable connection based on the received AC control signal.

2. The method of claim 1, wherein the shunt capacitance unit is adjacent to the remote radio head.

3. The method of claim 1, wherein determining the resistance or impedance of the power cable connection based on the received AC control signal comprises: the method further comprises measuring at least one of a voltage level or a current level of the received AC control signal, and calculating a resistance or impedance of the power cable connection based on the at least one measured voltage level and/or current level.

4. The method of claim 1, wherein the AC control signal is generated by a pulse generator of the power supply.

5. The method of claim 1, wherein the power cabling comprises a trunk cable and a jumper cable connected in series.

6. The method of claim 5, wherein the shunt capacitance unit is part of the jumper cable.

7. The method of claim 1, wherein a frequency of the AC control signal is lower than a transmission frequency of the remote radio head.

8. The method of claim 1, wherein determining the resistance or impedance of the power cable connection based on the received AC control signal comprises: calculating a resistance or impedance of the power cable connection using ohm's law based on the measured voltage level and/or current level.

9. The method of claim 1, wherein the frequency of the AC control signal is between 100 hertz and 100 kilohertz.

10. An inline connector module, comprising:

a housing;

a first connector on a first end of the housing configured to connect to a connector of a jumper cable;

a second connector on a second end of the housing, wherein the second connector is configured to mate with a connector that engages the housing or the remote radio head;

a power supply conductor and a return conductor disposed within the housing; and

a shunt capacitance unit within the housing connected between the power supply conductor and the return conductor, the shunt capacitance unit comprising at least one capacitor coupled between the power supply conductor and the return conductor.

11. The inline connector module of claim 10, wherein the at least one capacitor is a non-polar electrolytic capacitor.

12. The inline connector module of claim 10, wherein the at least one capacitor comprises a first capacitor and a second capacitor coupled in series between the power supply conductor and the return conductor.

13. The inline connector module of claim 12, further comprising a fuse circuit coupled in series between the first capacitor and the second capacitor.

14. The inline connector module of claim 10, wherein the at least one capacitor has a capacitance of at least 400 microfarads.

15. The inline connector module of claim 14, wherein the at least one capacitor has a capacitance of less than 2500 microfarads.

16. The inline connector module of claim 10, wherein the shunt capacitance unit is configured to reduce a voltage drop at a remote radio head due to spikes in a dc power signal carried by the jumper cable.

17. A method of power delivery, comprising:

attaching a first connector on a first end of an inline connector module to a connector of a jumper cable, wherein the inline connector module houses a power supply conductor, a return conductor, and a shunt capacitance unit therein, and wherein the shunt capacitance unit is connected between the power supply conductor and the return conductor and includes at least one capacitor coupled between the power supply conductor and the return conductor;

mating a second connector on a second end of the inline connector module with a mating connector, wherein the mating connector is a connector that engages a housing or a connector of a remote radio head; and

outputting a Direct Current (DC) power signal from a power source and supplying the DC power signal output from the power source to the remote radio head mounted remotely from the power source through the jumper cable and the inline connector module.

18. The method of claim 17, wherein the at least one capacitor comprises a first capacitor and a second capacitor coupled in series between the power supply conductor and the return conductor.

19. The method of claim 18, wherein the inline connector module further comprises a fuse circuit coupled in series between the first capacitor and the second capacitor.

20. The method of claim 17, further comprising determining that the at least one capacitor coupled between the power supply conductor and the return conductor has failed; and

replacing the shunt capacitance unit.

21. A cellular base station power supply system comprising:

a power source; and

a power cabling connection, wherein the power cabling connection includes a power supply conductor, a return conductor, and a shunt capacitance unit coupled between the power supply conductor and the return conductor, the shunt capacitance unit including at least one capacitor coupled between the power supply conductor and the return conductor;

wherein the power supply is configured to supply a first power signal and a second power signal to the power cabling connection, wherein the first power signal is a direct current, DC, power signal configured to supply power to a remote radio head mounted remotely from the power supply and coupled to a distal end of the power cabling connection, wherein the second power signal is an alternating current, AC, power signal configured to pass through the shunt capacitance unit, and wherein the power supply is configured to receive the AC power signal passing through the shunt capacitance unit and to measure at least one of a voltage level and a current level of the received AC power signal.

22. The cellular base station power supply system of claim 21, wherein the frequency of the AC power signal is between 100 hertz and 100 kilohertz.

23. The cellular base station power supply system of claim 21, wherein the power supply is configured to adjust the voltage level of the first power signal based on the measured voltage level and/or current level of the received AC power signal.

24. The cellular base station power supply system of claim 23, wherein the power supply is configured to determine a resistance or impedance of the power cable connection based on the measured voltage level and/or current level of the received AC power signal, and wherein the power supply is configured to adjust the voltage level of the first power signal based on the determined resistance or impedance of the power cable connection.

25. The cellular base station power supply system of claim 24, wherein determining a resistance or impedance comprises: calculating a resistance or impedance of the power cable connection based on the measured voltage level and/or current level.

26. The cellular base station power supply system of claim 24, wherein determining the resistance or impedance of the power cable connection based on the received AC power signal comprises: calculating a resistance or impedance of the power cable connection using ohm's law based on the measured voltage level and/or current level.

27. The cellular base station power supply system of claim 21 wherein the AC power signal is generated by a pulse generator of the power supply.

28. The cellular base station power supply system of claim 21, wherein the power cable connection comprises a trunk cable and a jumper cable connected in series.

29. The cellular base station power supply system of claim 28, wherein the shunt capacitance unit is part of the jumper cable.

30. The cellular base station power supply system of claim 21, wherein the frequency of the AC power signal is lower than a transmission frequency of the remote radio head.

31. A cellular base station power supply system comprising:

a power source; and

a power cabling connection, wherein the power cabling connection includes a power supply conductor, a return conductor, and a capacitance coupled between the power supply conductor and the return conductor;

wherein the power supply supplies a first power signal and a second power signal to the power cable connection, wherein the first power signal is a Direct Current (DC) power signal configured to supply power to a remote radio head mounted remotely from the power supply and coupled to a distal end of the power cable connection, wherein the second power signal is an Alternating Current (AC) power signal configured to pass through the capacitance, and wherein the power supply is configured to receive the AC power signal passing through the capacitance and determine a resistance or impedance of the power cable connection based on a measurement of the received AC power signal, and wherein the power supply is configured to adjust a voltage level of the first power signal based on the determined resistance or impedance of the power cable connection.

32. The cellular base station power supply system of claim 31, wherein the measurement of the received AC power signal comprises a measurement of a voltage level of the received AC power signal, and wherein determining the resistance or impedance comprises calculating the resistance or impedance of the power cable connection based on the measured voltage level.

33. The cellular base station power supply system of claim 31, wherein the power supply is configured to adjust the voltage level of the first power signal based on a change in the measured current level of the first power signal to provide a signal having a substantially constant voltage at the distal end of the power cable connection.

34. The cellular base station power supply system of claim 31, wherein the AC power signal is generated by a pulse generator of the power supply.

35. The cellular base station power supply system of claim 31, wherein the power cable connection comprises a trunk cable and a jumper cable connected in series.

36. The cellular base station power supply system of claim 35, wherein the capacitance is part of the jumper cable.

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