Patent Description:
Data centers are mission critical facilities which are used for housing IT equipment and servers. The variation in business requirements and use cases, variation in computing power requirements, etc. cause significant variation in IT equipment design. Data centers are expanding very fast, and their total energy consumption is also growing rapidly. Every year, companies with large data centers spend large sums of money on electricity. A need, therefore, exists for systems that can reduce electricity costs and more efficiently utilize power within data centers. Renewable power has started to attract a lot of attention from hyperscale data center owners. In addition, there is indeed a need of implementing renewable energy to accommodate environmental regulations. <CIT> discloses a DC power supply system including a power conditioner that supplies generated power W2 of a power generation apparatus to a DC bus; DC/DC converters that perform voltage conversion for a bus voltage Vbs and supply load power (WLa+WLb) to load devices; bidirectional DC/DC converters that supply DC constant current from the DC bus to storage batteries or from the storage batteries to the DC bus; and a power management apparatus. <CIT> discloses a distributed power system including a DC bus, at least one DC UPS configured to provide DC power to the DC bus derived from at least one of input AC power and backup DC power such that a DC voltage on the DC bus is maintained at a nominal level, and at least one power module configured to monitor the DC voltage on the DC bus, to convert DC power from an energy storage device into regulated DC power, and to provide the regulated DC power to the DC bus in response to a determination that the DC voltage on the DC bus is less than a threshold level.

In an aspect, there is provided a method of managing power from a plurality of photovoltaic (PV) energy systems according to claim <NUM>.

In another aspect, there is provided a data center system according to claim <NUM>.

Embodiments of the present disclosure provide an advanced solution for upgrading existing PV systems to IT clusters without requiring system adaptations to the existing PV systems or the IT clusters.

In the description of the embodiments provided herein, the terms "coupled" and "connected," along with their derivatives, may be used. "Coupled" is used to indicate that two or more elements, which may or may not be in direct physical or electrical contact with each other, cooperate or interact with each other. Additionally, the terms "server," "client," and "device" are intended to refer generally to data processing systems rather than specifically to a particular form factor for the server, client, and/or device.

Green energy systems, like wind turbines and solar panels, are increasingly lower in cost and also low in carbon emissions. However, the power produced by those intermittent resources is at times neither consistent nor predictable. Existing PV systems can be equipped with combined energy storage systems, which may be costly and complex to operate. It is desireable to implement renewable energy to continue supporting the increasing of power need and data center expanding under the environmental regulations and power usage limitations.

Embodiments of the present disclosure allow for integration of new PV systems to existing infrastructure. Instead of using controllers for each subsystem, in some embodiments a single controller can be utilized to control all of the PV subsystems and to add new solar panels to the system.

In an embodiment, not all of the PV systems require a current sensor. Instead of setting up current sensors and a test loop for every PV subsystem, the power levels of newly added PV systems can be predicted based on previously installed PV systems that do include current sensors. In this way, embodiments of the present disclosure provide an advanced solution for upgrading existing PV systems to IT clusters without requiring system adaptations to the existing PV systems or the IT clusters. Such embodiments can also facilitate scaling of PV systems according to the IT load.

Efficiently implementing renewable power systems, such as PV systems, into modern data centers can be challenging. According to an embodiment, the real time solar output power is considered to determine an operation mode for the system, in order to utilize solar power without extra energy storage systems needing to be added to the PV system. According to another embodiment, existing IT infrastructure can be upgraded to include a PV system without additional requirements on detection or control systems. Embodiments of the present disclosure provide a system that can be easily plugged into an existing infrastructure, and is fully compatible with an existing PV system and IT cluster. In addition, newly added PV systems, as well as the entire system, can be operated in multiple stages based on the newly upgraded capabilities. In some embodiments, the PV systems real time power output can be dynamically adjusted in multiple scenarios, including PV system upgrading, PV system degrading, PV system failure, regular maintenance, and so on.

According to one embodiment, the design and operation of a multi-PV system is disclosed. An example system design is disclosed, as well as the control flow for populating and operating a PV system, and utilizing the available renewable power efficiently. For ease of description, high level embodiments of the multiple systems are provided, including the electrical system architecture, and including the electrical connections among subsystems and the whole system. However, one skilled in the art will recognize that these embodiments do not limit the scope of the invention, and various other embodiments, architectures, and designs can be used.

In an embodiment, the system disclosed herein can operate in at least three modes of operation, including a disconnection mode, a connection mode, and a battery charging mode. To enable integration of new PV systems to upgrade existing systems, and to operation the renewable energy sources more efficiently to power data centers, a mathematical approach is disclosed below to enable a detection and estimation of solar power from an upgrade system, including operation of each individual newly added subsystem. Embodiments disclosed herein can enable the upgrading of renewable power systems in a simplified and cost effective means. The techniques disclosed herein can be used, for example, to integrate an existing architecture with additional PV systems, including PV systems that may or may not be equipped with battery storage systems.

<FIG> shows an example design of a power distribution system in a data center, according to an embodiment of the present disclosure. In this embodiment, there are N PV subsystems in total, some of which include current sensors and some of which do not. In this embodiment, the system includes S number of subsystems with current sensors, and N-s number of subsystems without current sensors. Specifically, the system includes a first PV system <NUM> with a corresponding DC/DC converter <NUM>, a current sensor <NUM>, and a first test resistance <NUM>. The DC/DC converter <NUM> and first test resistance <NUM> are selectively connected to the first PV system <NUM> using switches S1 and S2, in this example embodiment. Likewise, PV system S <NUM> is selectively connected to a DC/DC converter <NUM> and test resistance S <NUM> using switches S11 and S12. Current sensor S <NUM> is also located between the DC/DC converter <NUM> and test resistance S <NUM>. In this embodiment, the DC/DC converters <NUM>, <NUM>, <NUM>, <NUM> are used to normalize and regulate the output voltage of each PV system to a certain level for use (e.g. for charging batteries or powering other workloads).

In this embodiment, there are a total of N PV systems and N-s subsystems do not include current sensors. The N-s PV systems incudes PV system S+<NUM><NUM> and PV system N <NUM>. PV system S+<NUM><NUM> is connected to DC/DC converter <NUM>, and PV system N <NUM> is connected to DC/DC converter <NUM>. In an embodiment, each of the DC/DC converter <NUM>, <NUM>, <NUM>, <NUM> is connected to a DC bus <NUM>, <NUM>, <NUM>, <NUM>. In some embodiments, the DC buses <NUM>, <NUM>, <NUM>, <NUM> may be the same DC bus.

In the embodiment of <FIG>, each of the PV systems is selectively connected to a DC inter-system DC bus <NUM> via DC/DC converters <NUM>, <NUM>, <NUM>, <NUM> and switches S3, S13, S21, S31. The DC/DC converters <NUM>, <NUM>, <NUM>, <NUM> are used to convert the voltage to the same as that of the inter-system DC bus <NUM>.

Each PV system includes a corresponding storage system, in this embodiment. In some embodiments, the PV systems can coexist with a more centralized storage system for powering the DC bus. These storage systems corresponding to each PV system include storage system <NUM><NUM>, storage system S <NUM>, storage system S+<NUM><NUM>, and storage system N <NUM>. Each of these storage systems are selectively connected to the inter-system DC bus <NUM> using switches S4, S14, S22, and S32. In some embodiments, each of the S+<NUM> through N PV systems may not need its own dedicated storage system, and two or more of the PV systems can share a storage system.

In the embodiment of <FIG>, N clusters are also selectively connected to the inter-system DC bus <NUM>. These clusters include cluster <NUM><NUM>, cluster S <NUM>, cluster S+<NUM><NUM>, and cluster N <NUM>, which are selectively connected to the inter-system DC bus <NUM> using switches S5, S15, S23, S33. In an embodiment, the system also includes a central controller <NUM> and a PV controller <NUM>. The PV controller <NUM> can monitor readings from the current sensors <NUM> and <NUM>, and can operate the PV system switches S1, S2, S11, and S12. Controller <NUM> can be used to operate switches S3, S4, S5, S13, S14, S15, S21, S22, S23, S31, S32, and S33 in some embodiments, and can interact with the PV controller <NUM>. As will be appreciated, the controller <NUM> and PV controller <NUM> can be separate elements or can be integrated into a single controller in some embodiments.

Whenever a subsystem has solar power available, the PV resources can be connected to the inter-system DC bus <NUM> and can be used to serve the clusters <NUM>, <NUM>, <NUM>, <NUM>, or to charge the storage systems <NUM>, <NUM>, <NUM>, <NUM>. The switches in this embodiment have at least two goals: system operation for operating power flow for powering the data center IT clusters, and to enable modular system design and service/maintenance considerations.

Example operating scenarios include the following: For newly built systems, subsystems <NUM> through S can be integrated first, and then systems S+<NUM> through N can be integrated. For existing systems having PV systems S+<NUM> through N, these systems may be equipped with energy storage systems or batteries, and then systems <NUM> through S can be integrated so that overall control can be switched to these systems with sensors. For existing systems including PV systems <NUM> through N, subsystems <NUM> through S can be integrated or retrofitted to implement the operating strategy and control techniques described herein.

<FIG> shows another example design of a power distribution system in a data center, according to an embodiment of the present disclosure. In this embodiment, the system includes three PV subsystems. The first PV system <NUM> and the second PV system <NUM> are connected to current sensors <NUM> and <NUM>, respectively. The first PV system <NUM> is selectively connected to DC/DC converter <NUM> using switch S1, and is selectively connected to the first test resistance <NUM> using switch S2. Likewise, the second PV system <NUM> is selectively connected to DC/DC converter <NUM> using switch S11, and is selectively connected to the second test resistance <NUM> using switch S12. The system also includes PV system <NUM><NUM> that is connected to DC/DC converter <NUM> without any current sensors. Each of the DC/DC converters <NUM>, <NUM>, <NUM> is connected to a DC bus <NUM>, <NUM>, <NUM>. This means this system <NUM> will be operated based on the other two PV system sensors.

In the embodiment of <FIG>, each of the PV systems is selectively connected to a DC inter-system DC bus <NUM> via DC/DC converters <NUM>, <NUM>, <NUM> and switches S3, S13, S21. The DC/DC converters <NUM>, <NUM>, <NUM> are used to convert the voltage to the same as that of the inter-system DC bus <NUM>.

Each PV system coexist with a corresponding storage system, in this embodiment. These storage systems include storage system <NUM><NUM>, storage system <NUM><NUM>, and storage system <NUM><NUM>. Each of these storage systems is selectively connected to the inter-system DC bus <NUM> using switches S4, S14, and S22. In an embodiment, this storage system can be either a dedicated energy backup unit in the data center or an existing one used in the utility power line.

In the embodiment of <FIG>, three clusters are also selectively connected to the inter-system DC bus <NUM>. These clusters include cluster <NUM><NUM>, cluster <NUM><NUM>, and cluster <NUM><NUM>, which are selectively connected to the inter-system DC bus <NUM> using switches S5, S15, S23. In an embodiment, the system also includes a central controller <NUM> and PV controller <NUM>. The PV controller <NUM> can monitor readings from the current sensors <NUM> and <NUM>, and can operate the PV system switches S1, S2, S11, and S12. Controller <NUM> can be used to operate switches S3, S4, S5, S13, S14, S15, S21, S22, and S23 in some embodiments, and can interact with the PV controller <NUM>. As will be appreciated, the central controller <NUM> and PV controller <NUM> can be separate elements or can be integrated into a single controller in some embodiments.

Three example operation modes of this system are described below and illustrated in <FIG>. <FIG> shows an example design of the power distribution system of <FIG> in a disconnection mode, according to an embodiment of the present disclosure. In this mode of operation, the central controller <NUM> sends a signal to the PV controller <NUM>, and the PV controller <NUM> retrieves the current data from the sensors <NUM>, <NUM> and finds that there is no solar power available at the present time. This information is then relayed back to the central controller <NUM>. Thus, switches S3, S4, S5, S13, S14, S15, S21, S22, and S23 remain open wile switches S1, S2, S11, and S12 are closed.

<FIG> shows an example design of the power distribution system of <FIG> in a battery charging mode, according to an embodiment of the present disclosure. In this mode of operation, the central controller <NUM> sends a signal to the PV controller <NUM>, and the PV controller <NUM> retrieves the current data from sensors <NUM>, <NUM> and finds that there is solar power at present that can be used to charge the storage systems. This information is relayed to the central controller <NUM>, which determines that the first storage system <NUM> will receive the available solar power. In this mode of operation, switches S5, S15, and S23 are open and switches S3, S13, and S21 are closed to connect all of the PV systems to the inter-system DC bus <NUM>. One or more of switches S4, S14, and S22 are closed to charge one or more of the subsystems. In this example embodiment, S4 is closed to charge the first storage system <NUM>, while S14 and S22 are open. In some embodiments, the storage system to be charged can be chosen by considering the state of the battery and the state of the components within the subsystem. In this embodiment, the detection circuit remains a closed circuit with switches S1, S2, S11, and S12 closed.

<FIG> shows an example design of the power distribution system of <FIG> in a connection mode, according to an embodiment of the present disclosure. In this mode of operation, the PV controller <NUM> retrieves current data from the sensors <NUM>, <NUM> and determines that there is sufficient solar power available. Thus, switches S3, S13, and S21 are closed to connect all of the PV systems to the inter-system DC bus <NUM>. However, in this embodiment the total solar power exceeds the bus connection threshold, so switches S4, S14, and S22 are open and S1, S2, S11, S12 are closed along with S3, S13, and S21 to provide the solar power to one of the clusters. In this embodiment, the first cluster <NUM> is connected to the inter-system DC bus <NUM> using switch S5, while the second cluster <NUM> and third cluster <NUM> remain disconnected with switches S15 and S23 open.

<FIG> is a flow diagram of an example method for distributing power within a data center, according to an embodiment of the present disclosure. The power distribution method <NUM> can be implemented, for example, using the power distribution systems described in <FIG>. At operation <NUM>, the method <NUM> measures an output of a subset of PV energy systems which include current sensors. Within the data center, the remaining PV energy systems do not include current sensors.

At operation <NUM>, the total power of all of the PV energy systems is calculated based on the measured output of the subset of PV energy systems. In some embodiments, where the PV energy systems without current sensors include the same type of PV cell as the PV energy systems with sensors, the total power can be calculated by applying a power level of each of the PV systems with sensors to those without sensors.

In some embodiments, where the PV systems without sensors are the same type as those with sensors, the total power can be calculated by multiplying by a ratio proportional to the number of panels of the sensor-less PV systems divided by the number of panels in the PV systems with sensors. Weights can be randomly selected for each of the PV systems without sensors, in some embodiments. The highest and lowest values from the randomly selected weights can be removed, and an average value can be calculated for the remaining power levels.

In operation <NUM>, a charging level threshold for the storage systems is determined. In operation <NUM>, a power threshold for the IT clusters within the data center is determined.

In operation <NUM>, energy from the PV energy systems is selectively used to charge the storage systems or the IT clusters. In some embodiments, when the total PV power is higher than the charging level threshold for the storage systems but below the power threshold for the IT clusters, the PV power can be used to charge the storage systems. If the total PV power is above the power threshold for the IT clusters, the PV power can be used to power one or more of the IT clusters.

<FIG> is a flow diagram of another example method <NUM> for distributing power within a data center, according to an embodiment of the present disclosure. The power distribution method <NUM> can be implemented, for example, using the power distribution systems described in <FIG>. In this embodiment, two thresholds are used in the control logic: the charging level threshold, and the bus connection threshold (i.e. the power threshold for the IT clusters).

The method <NUM> begins at <NUM> in an initial state of operation. With reference to the systems described in <FIG>, all the switches are open in this initial state except for switches S2 and S12.

At operation <NUM>, the method <NUM> detects signals for checking whether there is any available PV power. If a signal exits, the information of the output current of the PV systems is measured at operation <NUM>. The current can be measured by closing switches S2 and S12, opening all other switches, and having the PV controller measures the values at current sensors <NUM> and <NUM>.

At operation <NUM>, the total amount of solar power of the whole system is calculated. In an embodiment, the total power can be calculated according to the equations below, where Ptotal stands for the total solar power of the whole system at present, and the first term corresponds to the solar power of the subsystems which have current sensors, this means the output of these subsystems are measurable directly. <MAT> <MAT> <MAT> <MAT>.

In equations (<NUM>) and (<NUM>), W(I) is the function which can transfer current to power for the subsystem, and I is the current that is measured from the sensor. In equation (<NUM>), δ is proportional to the output voltage value of the PV panel in the certain subsystem. In an embodiment, δ needs to be tuned for different systems, since the δ is based on both the detection circuit including the test resistance as well as the PV system itself. The function f(αkt) is a transfer function which can be used to calculate the solar power output of other subsystems which do not have sensors, and is proportional to the deviation of Pk and Pt, where Pk is the rated power of the subsystem that does not have any sensors, and Pt is the power of the subsystem that has a sensor. When the subsystems which have sensors are the same as, or made by the same company as those without sensors, only a number of panels is involved in the transfer function. This transfer function can be understood as representing the output power relationships of two systems under the same environment. Therefore, with one system measured, the other one can be calculated. This transfer function also can be developed or tuned based on the actual system. Here we introduce some of the methods which may be used in the following sections.

In equation (<NUM>), αP is a constant factor and it can be treated as <NUM> as a default. In an embodiment, N<NUM> and N<NUM> correspond to the numbers of panels of PV system <NUM> and <NUM>, respectively, while αN is a constant factor which can be set as a default to <NUM>. Constants αP and αN can be adjusted in order to tune the accuracy of the system.

In equations (<NUM>) and (<NUM>), φt is used as the weight of each subsystem t, while the sum of weights adds up to one and the weight can be calculated using a randomized algorithm. The output solar power of one subsystem which does not have sensors can be calculated as a weighted sum of the solar power produced by the subsystems that have sensors, in some embodiments.

The transfer function is proportional to the power generation abilities of the solar panels, which can be related to the materials, number of panels, etc. Considering the differences of the PV panels in those subsystems, three conditions are outlined above in equations (<NUM>) through (<NUM>).

At operation <NUM>, it is determined whether the total power exceeds the battery charging threshold. If not, the PV systems are disconnected, or are kept disconnected, from the inter-system DC bus in operation <NUM>. In operation <NUM>, if the PV systems are initially connected to the inter-system bus they can be disconnected, and if they are not connected they remain disconnected. This can be performed in the disconnected operating mode shown in <FIG>, for example.

If the total power does exceed the battery charging threshold, the PV systems can be connected to the inter-system DC bus at operation <NUM>. This may be performed by closing switches S1, S2, S3, S11, S12, S13, and S21 so that the power from the PV systems can be directed to the inter-system DC bus <NUM>.

At operation <NUM>, it is determined whether the total PV power exceeds the bus connection threshold for the IT clusters. If not, the inter-system bus is connected, at operation <NUM>, to one or more of the storage systems to charge the storage systems using PV power. An example of this mode of operation is described above in reference to <FIG>.

If the total PV power exceeds the bus connection threshold, then one or more of the clusters are connected to the inter-system bus to power the cluster using PV power at operation <NUM>. An example of this mode of operation is described above in reference to <FIG>.

<FIG> is a flow diagram of an example method <NUM> for integrating PV power systems within a data center, according to an embodiment of the present disclosure. The method <NUM> can be implemented, for example, using the power distribution system described in <FIG>. At operation <NUM>, one or more new PV subsystems that do not include any current sensors are added to a current PV energy system.

At operation <NUM>, the method <NUM> determines whether the one or more new PV systems are the same type of system as the current PV systems that have sensors. If it is the same type of PV system (e.g. the same type of solar panels or from the same manufacturer), then the method <NUM> continues to operation <NUM> and the power of the new PV system is calculated using a deviation of the number of solar panels. The power of the new PV system can be calculated directly, simply based on the number of panels included in the new PV system, or by multiplying a ratio that is proportional to the number of new solar panels divided by the number of previous solar panels that have sensors.

If it is determined at operation <NUM> that the new PV system is not the same type as the current PV systems that include sensors, the method <NUM> continues with operation <NUM> and randomly selects weights for k times, where k is the number of new PV systems being added, and calculates the power for those weights.

At operation <NUM>, the highest and lowest results for each of the randomly selected weights is removed, and the average of the k-<NUM> calculations is generated. At operation <NUM>, the average value of the results which meet system requirements is calculated in order to determine the output power of the new subsystem. For example, results that meet system requirements may include results that have larger difference from the mean value of the entire set of results. In an embodiment where there are two or more identical highest or lowest results, each of those results would not meet system requirements.

In some embodiments, the methods described herein can be used implemented using an artificial intelligence (AI) and/or machine learning (ML) neural network that is trained to determine or calculate the predicted output power of a new subsystem. For example, the measured values for the PV systems that include sensors, and the weighted power values calculated for the new PV systems (as well as the averaged calculations described above) can be used to train a neural network that can calculate the estimated power produced by new PV systems that do not include sensors, as well as the total power of the PV systems. As another emample, the δ shown in the equations above and the transferred functions can be achieved with AI technqiues.

Embodiments of the invention also relate to an apparatus for performing the operations herein. Such a computer program is stored in a non-transitory computer readable medium. A machine-readable medium includes any mechanism for storing information in a form readable by a machine (e.g., a computer). For example, a machine-readable (e.g., computer-readable) medium includes a machine (e.g., a computer) readable storage medium (e.g., read only memory ("ROM"), random access memory ("RAM"), magnetic disk storage media, optical storage media, flash memory devices).

The processes or methods depicted in the preceding figures may be performed by processing logic that comprises hardware (e.g. circuitry, dedicated logic, etc.), software (e.g., embodied on a non-transitory computer readable medium), or a combination of both. Although the processes or methods are described above in terms of some sequential operations, it should be appreciated that some of the operations described may be performed in a different order. Moreover, some operations may be performed in parallel rather than sequentially. Embodiments described herein are not described with reference to any particular programming language. It will be appreciated that a variety of programming languages may be used to implement the teachings of embodiments of the invention as described herein.

One skilled in the art would recognize that various adjustments can be made to the system within the scope of this disclosure.

The following clauses and/or examples pertain to specific embodiments or examples thereof. Specifics in the examples may be used anywhere in one or more embodiments. Various components can be a means for performing the operations or functions described.

One embodiment provides for a method of managing power from a plurality of photovoltaic (PV) energy systems. The method includes measuring an output of a subset of PV energy systems, where each of the subset of PV energy systems includes a corresponding current sensor, and the remainder of the PV energy systems do not have current sensors. The method also includes calculating a total power of all of the PV energy systems based on the measured output of the PV energy systems with sensors. The method also includes determining a charging threshold for one or more storage systems, and determining a power threshold of one or more IT clusters within a data center. The method also includes selectively utilizing energy from the PV energy systems to charge the storage systems or power the IT clusters. In one embodiment, the PV energy systems without current sensors include the same type of PV cell as the PV energy systems with sensors, and calculating the total power includes applying a power level of each of the PV energy systems with sensors to each of the PV energy systems without sensors. In one embodiment, the PV energy systems without current sensors include a same type of PV cell as the subset of PV energy systems, and calculating the total power includes multiplying by a ratio which is proportional to a number of panels of the PV energy systems without current sensors divided by a number of panels of the subset of PV energy systems. In one embodiment, calculating the total power includes calculating power levels for each of the PV energy systems without current sensors by numerically selecting weights for each of the PV energy systems without current sensors. In one embodiment, calculating the total power also includes: removing power level calculations corresponding to highest and lowest values from each of the weights for the PV energy systems without current sensors; and calculating an average value of the remaining power level calculations. In one embodiment, calculating the total power includes: utilizing a machine learning (ML) neural network to calculate a predicted output power of the PV energy systems without current sensors; and calculating the total power based on the predicted output power calculated using the ML neural network. In one embodiment , the total power is above the charging threshold for one or more storage systems and below the power threshold of one or more IT clusters, and energy from the plurality of PV energy systems is used to charge the one or more storage systems. In one embodiment, the total power is above the charging threshold for one or more storage systems and above the power threshold of one or more IT clusters, and energy from the plurality of PV energy systems is used to power the one or more IT clusters.

Another embodiment of the present disclosure includes a data center. The data center includes a number of PV energy systems, a subset of PV energy systems including current sensors, and a remainder of the PV energy systems without current sensors. The data center also includes one or more storage systems, one or more IT clusters, and at least one power controller. The power controller is configured to measure an output of the PV energy systems with current sensors; and calculate a total power of all of the PV energy systems based on the measured output of the PV energy systems with sensors. The power controller is also configured to determine a charging threshold for the one or more storage systems, and determining a power threshold of the one or more IT clusters. The power controller is also configured to selectively utilize energy from the PV energy systems to charge the storage systems or power the IT clusters. In one embodiment, the PV energy systems without current sensors include the same type of PV cell as the PV energy systems with sensors, and the power controller is configured to calculate the total power by applying a power level of each of the PV energy systems with sensors to each of the PV energy systems without current sensors. In one embodiment, the PV energy systems without current sensors include the same type of PV cell as the PV energy systems with current sensors, and the power controller is configured to calculate the total power by multiplying by a ratio which is proportional to a number of panels of the PV systems without current sensors divided by a number of panels of the PV energy systems with current sensors. In one embodiment, the power controller is also configured to: receive one or more additional PV energy systems without current sensors; and manage and operate all the PV energy systems in different modes of operations, the modes of operation including a disconnected mode, a charging mode for charging the one or more storage systems, and a connected mode for powering the one or more IT clusters. In one embodiment, calculating the total power includes: utilizing a machine learning (ML) neural network to calculate a predicted output power of the PV energy systems without current sensors; and calculating the total power based on the predicted output power calculated using the ML neural network. In one embodiment, the total power is above the charging threshold for one or more storage systems and below the power threshold of one or more IT clusters, and energy from the plurality of PV energy systems is used to charge the storage systems. In one embodiment, the total power is above the charging threshold for one or more storage systems and above the power threshold of one or more IT clusters, and energy from the plurality of PV energy systems is used to power the IT clusters.

Another embodiment of the present disclosure includes a method for integrating photovoltaic (PV) power systems within a data center. The method includes adding at least one new PV energy system that does not include a current sensor to the data center. The method also includes determining whether the new PV energy system includes the same type of PV cell as previously installed PV energy systems. If the new PV energy system includes the same type of PV cell as the previously installed PV energy systems, the method includes calculating a total power of all PV energy systems by applying a power level of each of the previously installed PV energy systems to each of the new PV energy systems. If the new PV energy system does not include the same type of PV cell as the previously installed PV energy systems, the method includes calculating the total power of all PV energy systems by multiplying by a ratio which is proportional to a number of panels of the new PV energy systems divided by a number of panels of the previously installed PV energy systems. In one embodiment, the new PV energy system does not include the same type of PV cell as the previously installed energy systems, and calculating the total power includes: calculating power levels for each of the new PV systems without current sensors by numerically electing weights for each of the new PV systems without current sensors. In one embodiment, calculating the total power further includes: removing power level calculations corresponding to highest and lowest values from each of the numerically selected weights for each of the new PV systems; and calculating an average value of remaining power level calculations. In one embodiment, the total power is above a charging threshold for one or more storage systems and below a power threshold of one or more IT clusters, and energy from the all PV energy systems is used to charge the storage systems. In one embodiment, the total power is above a charging threshold for one or more storage systems and above a power threshold of one or more IT clusters, and energy from all PV energy systems is used to power the IT clusters.

Claim 1:
A method (<NUM>) of managing power from a plurality of photovoltaic (PV) energy systems, wherein a subset of PV energy systems includes PV energy systems each with a corresponding current sensor and a remainder of the PV energy systems includes PV energy systems without current sensors, the method comprising:
measuring (<NUM>) an output power of the subset of PV energy systems;
calculating (<NUM>) a total power of all of the PV energy systems based on the measured output power of the subset of PV energy systems;
determining (<NUM>) a charging power threshold for one or more storage systems;
determining (<NUM>) a power threshold of one or more IT clusters within a data center; and
selectively (<NUM>) utilizing energy from the plurality of PV energy systems to charge the one or more storage systems or power the one or more IT based on a comparison of the calculated total power with the charging power threshold for the one or more storage systems and the power threshold of the one or more IT clusters.