Systems And Methods Of Dynamic Mimo Antenna Configuration And/Or Reconfiguration For Portable Information Handling Systems
Systems and methods may be implemented with MIMO antenna architectures (e.g., such as 2×2, 3×3, 4×4, etc.) of a given mobile information handling system to selectively use dynamic MIMO configuration and/or reconfiguration to select only a subset of the available multiple antenna elements or all of the available multiple antenna elements for receive and/or transmit operation based on the interference characteristics of the given mobile information handling system and/or based on the current radio frequency (RF) band currently being used for wireless communications by the mobile information handling system.
This invention relates generally to portable information handling systems and, more particularly, to antenna configuration for wireless transmission from information handling systems.
BACKGROUNDAs the value and use of information continues to increase, individuals and businesses seek additional ways to process and store information. One option available to users is information handling systems. An information handling system generally processes, compiles, stores, and/or communicates information or data for business, personal, or other purposes thereby allowing users to take advantage of the value of the information. Because technology and information handling needs and requirements vary between different users or applications, information handling systems may also vary regarding what information is handled, how the information is handled, how much information is processed, stored, or communicated, and how quickly and efficiently the information may be processed, stored, or communicated. The variations in information handling systems allow for information handling systems to be general or configured for a specific user or specific use such as financial transaction processing, airline reservations, enterprise data storage, or global communications. In addition, information handling systems may include a variety of hardware and software components that may be configured to process, store, and communicate information and may include one or more computer systems, data storage systems, and networking systems.
Multiple-input and multiple-output (MIMO) wireless technology is used to multiply the capacity of a radio link using multiple transmit and receive antennas for wireless communication to and from mobile information handling systems, including wireless communication using 802.11 Wi-Fi standards, HSPA+(3G), WiMAX (4G), and Long Term Evolution (4G). MIMO technology employs multiple antennas at both the transmitter and the receiver to send and receive multiple data signals on the same radio channel at the same time via multipath propagation. Conventional MIMO mobile computing product designs for information handling systems include those that target a 3×3 Wi-Fi antenna solution that employ three co-located Wi-Fi antenna elements that are installed in a small space on a mobile information handling system such as a laptop computer. Multiple MIMO antenna elements typically need to have at least a one quarter wavelength separation distance from each other to secure satisfactory antenna isolation for 2.4 GHz Wi-Fi band operation, while also requiring a similar separation distance from nearby metallic objects such as hinges, and from known noise sources such as embedded display port (eDP) cables and connectors.
SUMMARYDisclosed herein are systems and methods that may be implemented with MIMO antenna architectures (e.g., such as 2×2, 3×3, 4×4, etc.) of a given mobile information handling system to selectively use dynamic MIMO configuration and/or reconfiguration to select only a subset of the available multiple antenna elements based on the interference characteristics of the given mobile information handling system and/or based on the current radio frequency (RF) band currently being used for wireless communications by the mobile information handling system. In this regard, the disclosed systems and methods may be implemented to select different groups of currently-active antenna elements for use with different respective identities of information handling system configurations (e.g., each configuration identity having different RF interference characteristics), and/or to select different groups of currently-active antenna elements for use with different respective RF frequency bands currently utilized by a given information handling system configuration. Such selection may be made in one embodiment to achieve a reduction in the potential for RF interference imparted to RF communications at a RF frequency band that is currently utilized by the mobile information handling system configuration.
In one embodiment, the disclosed systems and methods may be implemented to automatically and dynamically select only a portion of the total number of antenna elements of an information handling system for MIMO operation in more interference-sensitive RF frequency bands and for information handling system configurations having relatively greater RF interference characteristics at such more interference-sensitive RF bands, while a larger number of the total number of antenna elements may be selected for MIMO operation in less interference-sensitive RF bands and for information handling system configurations having relatively less or no RF interference characteristics at such less interference-sensitive RF bands.
For example, in one exemplary embodiment, the disclosed systems and methods may be implemented to select a subset of antenna elements (e.g., two antenna elements of a 3×3 MIMO configuration) to be driven for 2.4 GHz Wi-Fi 802.11ac and 802.n frequency band operation that are furthest from an embedded display port (eDP) or other RF noise source (e.g., such as broadband noise source, clock frequency harmonics from system components such as display panels and display cables/connectors, system clocks, graphics/CPU chips, high speed transmission lines, other system antennas, etc.) of an information handling system, while selecting all antenna elements (e.g., all three antenna elements of the 3×3 MIMO configuration) of the same information handling system to be driven for 5 GHz Wi-Fi 802.11ac and 802.11n frequency band operation. Thus, in one embodiment, the disclosed systems and methods may be implemented to intelligently provide a dynamic solution for information handling systems to deliver best possible MIMO performance by using a greater number (or all) of available antenna elements while operating in a less interference-sensitive frequency band (e.g., such as a 5 GHz Wi-Fi band), while at the same time avoiding or substantially reducing noise interference due to close proximity of one or more of the available antenna elements to noise sources (e.g., such as embedded display port components) when operating in a more interference-sensitive frequency band (e.g., such as a 2.4 GHz operating band). In this way, the disclosed systems and methods may be implemented in one embodiment to intelligently address and prevent or substantially reduce interference problems that may impact performance of a given mobile information handling system configuration that is designed to support multiple antennas to deliver best-in-class MIMO (e.g., 3×3 Wi-Fi 11ac) end user performance. Thus, for example, the disclosed dynamically configurable and/or reconfigurable MIMO topology allows for maximum MIMO 3×3 5 GHz antenna performance, while isolating 2.4 GHz band from noise sources.
In one exemplary embodiment, a wireless radio module (e.g., such as a Wi-Fi module) may be provided having at least one processing device that is configured to execute software, firmware or other dynamic MIMO configuration logic that is configured to query and determine the identity of a current information handling system design or configuration into which the radio module is installed, and to then respond to this determined identity by only enabling antenna reconfiguration aspects of the dynamic MIMO configuration logic on the identified current information handling system if the wireless performance (e.g., wireless 802.11n/ac performance) of the current system is capable of benefiting from the dynamic reconfiguration methodology. Thus, for example, existing dynamic MIMO reconfiguration logic of a radio module may only activate antenna reconfiguration capability at system build time or any other time when the radio module is installed in a given information handling system design having a MIMO antenna configuration that exhibits particular RF interference characteristics for one or more RF frequency bands, but not activated when the same radio module is installed in another given information handling system design that has a MIMO antenna configuration that exhibits reduced or substantially no RF interference characteristics for one or more RF frequency bands.
One example of an information handling system design having a MIMO antenna configuration that exhibits RF interference characteristics for one or more RF frequency bands is an end-user computing (EuC) system including a MIMO configuration that employs multiple antennas that are co-located in a relatively small cavity of a mobile information handling system chassis with strong proximity effects. Examples of such MIMO configurations include, but are not limited to, 3×3 Wi-Fi 802.11ac applications, or any other MIMO Wi-Fi application employing a greater or lesser number of co-located multiple antennas, e.g., co-located within a hinge-cap cavity of a mobile information handling system cavity. Since the disclosed systems and methods may implemented to dynamically select only those co-located antennas of a system that are suitably spaced from each other and/or from RF noise sources (e.g., such as integral eDP components of the system that are transmitting audio signals, video signals, data signals or a combination thereof) to ensure little or substantially no interference for a current wireless frequency band, the co-located antennas of the system may be physically placed at a relatively close distance to each other and/or to any eDP noise source to satisfy substantially noise free operation for a most noise-resistance frequency band (e.g., such as 5 GHz Wi-Fi 802.11ac/n operation), while also enabling substantially noise free operation for less noise resistance frequencies (e.g., such as 2.4 GHz Wi-Fi 802.11ac/n operation) by dynamically only selecting a subset of the co-located antennas for the less noise resistance frequencies.
In one embodiment, dynamic MIMO configuration and/or reconfiguration may be implemented to ensure that design requirements for smaller information handling system platforms are met for the less noise resistant frequencies without the need for physically placing multiple co-located antennas (e.g., for 3×3 MIMO or higher order MIMO antenna configurations placed in the hinge cavity of a small information handling system platform) at a known increased minimal separation distance from the eDP connector for noise mitigation in the less noise resistant frequencies (e.g., 2.4 GHz band), reducing the number of co-located MIMO antenna elements, or co-locating only some (e.g., two) of the Wi-Fi antenna elements in a constrained cavity space of a smaller system and placing other (e.g., a third) antenna elements in a different location on the platform, as would be typically required for a conventional information handling system. In this regard, such conventional solutions for this potential interference problem at less noise resistant RF frequencies would be to reduce the desired number of MIMO antennas in a manner that fails to meet design specifications for smaller system platforms and/or to reduce isolation between the co-located antennas such that MIMO performance is compromised, leading to degraded end user wireless performance and/or resulting in unacceptable industrial design (ID), mechanical engineering (ME) and cost impacts for such conventional information handling systems that do not employ the dynamic MIMO configuration and/or reconfiguration disclosed herein.
In one respect, disclosed herein is a mobile information handling system, including: a host processing device; at least two available multiple input, multiple output (MIMO) antenna elements; and at least one radio module coupled between the host processing device and each of the available MIMO antenna elements, the radio module including at least one processing device and being configured to process and combine separate RF signals received in at least a common first frequency band from each of the available MIMO antenna elements to produce incoming data provided to the host processing device, and/or to process outgoing data provided from the host processing device to produce and transmit separate RF signals in the common first frequency band from each of the available MIMO antenna elements. The processing device of the radio module may be configured to determine the identity of a system chassis configuration of the mobile information handling system, and to then respond in real time to this determined identity by at least one of: dynamically configuring and/or reconfiguring a subset of the available MIMO antenna elements that are actively utilized to receive separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are received by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are received by all of the available MIMO antenna elements; or dynamically configuring and/or reconfiguring a subset of the available MIMO antenna elements that are actively utilized to transmit separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are transmitted by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are transmitted by all of the available MIMO antenna elements; or a combination thereof.
In another respect, disclosed herein is a method of operating a mobile information handling system, including using at least one processing device of a radio module of the information handling system to: process and combine separate RF signals received in at least a common first frequency band from each of at least two available multiple input, multiple output (MIMO) antenna elements to produce incoming data provided to a host processing device of the information handling system, and/or to process outgoing data provided from the host processing device to produce and transmit separate RF signals in the common first frequency band from each of the available MIMO antenna elements; determine the identity of a system chassis configuration of the mobile information handling system; and then respond in real time to the determined identity by at least one of: dynamically configuring and/or reconfiguring a subset of the available MIMO antenna elements that are actively utilized to receive separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are received by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are received by all of the available MIMO antenna elements; or dynamically configuring and/or reconfiguring a subset of the available MIMO antenna elements that are actively utilized to transmit separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are transmitted by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are transmitted by all of the available MIMO antenna elements; or a combination thereof.
Still referring to
In the particular embodiment of
When a battery system of a portable information handling system is optionally provided as a replaceable battery pack, it may be configured for insertion and removal from a corresponding battery pack compartment defined within the chassis of the information handling system (e.g., such as a notebook computer), and may be provided with external power and data connector terminals for contacting and making interconnection with mating power connector terminals and data connector terminals provided within the battery pack compartment to provide power to the system load (i.e., power-consuming components) of the information handling system and to exchange data with one or more processing devices of the information handling system.
Still referring to
Also shown in
Each of radio transceivers in baseband+RF processing devices 290 and 292 may be configured to perform intermediate frequency (IF) to RF up conversion mixing, amplification and RF processing tasks for outgoing transmitted signals to antennas 282, and vice-versa (including down conversion) for incoming received signals from antennas 282. Besides IF, transceivers in baseband+RF processing devices 290 and 292 may perform up conversion and down conversion between RF and other suitable frequencies for processing by baseband processing devices 290 and 292, e.g., such as zero-IF frequency, baseband frequency, etc. In this regard, baseband processing devices 290 and 292 (e.g., digital signal processor “DSP” or other suitable radio module or processing device/s) may each be coupled to exchange outgoing and incoming IF or other suitable signals with front ends 294 through respective digital-to-analog (DAC) and analog-to-digital (ADC) converters (not shown). Baseband processing devices 290 and 292 may be configured to manage RF signal transmission and reception, as well as to perform tasks including signal processing, encoding, frequency shifting and/or modulation operations to provide transmitted information in outgoing signals based on digital data provided by host processing device 205, and to perform signal processing, decoding, frequency shifting and/or demodulation operations to obtain the message content in the incoming signals as digital data to provide to host processing device 205. Each front end component 294 may perform transmit and receive functionality with integrated low noise amplifier to amplify attenuated receive signals, and power amplifier to amplify transmit signals to facilitate MIMO functionality and performance.
As further shown in
In this regard, it will be understood that the same configuration of radio module 280 may be installed in information handling system platforms having different chassis configurations that each have different RF interference characteristics. For example, relatively greater potential for RF interference to 2.4 GHz RF communications exist in a first system platform configuration where one or more of multiple antenna elements 2821 to 2823 are co-located adjacent an eDP noise source in a relatively small hinge cap cavity of a mobile information handling system such as notebook computer, while relatively lesser potential for RF interference to 2.4 GHz RF communications may exist in a second and different system platform configuration where multiple antenna elements 2821 to 2823 are co-located in a larger cavity (or different cavities) of a larger mobile information handling that has more room to sufficiently space all of antenna elements 2821 to 2823 away from eDP noise sources and from each other so as to substantially prevent RF noise interference in the 2.4 GHz band. Moreover, in the case of the first system platform configuration, little or substantially no RF interference to 5 GHz band communications may exist from the same eDP noise source that causes RF interference with 2.4 GHz communications. It will be understood that 2.4 GHz and 5 GHz frequency bands are just one exemplary combination of different first and second frequencies having different interference susceptibility. Thus in other embodiments, the disclosed systems and methods may be implemented for dynamic configuration and reconfiguration of multiple MIMO antenna elements of mobile information handling systems that are enabled to operate with combinations of two or more different frequency bands (e.g., other than 2.4 GHz and/or 5 GHz) that having different interference susceptibility to RF noise sources.
However, antenna element 2821 is spaced apart from noise source 302 by a distance “X” which is which is less than a minimum distance (e.g., 25 millimeters) required to prevent undesired interference to 2.4 GHz RF communications from RF noise 304 produced by noise source 302. In this regard, Wi-Fi 2.4 GHz band (e.g., 802.11b/g/n) is directly affected by broadband noise of noise source 302 which compromises Wi-Fi signal integrity and will directly impact end-user experience due to the relatively close proximity of antenna 2821 to noise source 302, i.e., antenna 2821 is placed closer than 25 mm away from RF noise source 302. However, Wi-Fi 5 GHz band (e.g., 802.11a/n/ac) is not affected by broadband noise emitted from noise source 302, and thus 5 GHz Wi-Fi communications are capable of taking full advantage of all three antennas 2821 to 2823 of the 3×3 MIMO antenna configuration of
It will be understood that 25 millimeters is just one example of a recommended minimum keep out distance from an antenna element 282 to a low-voltage differential signaling (LVDS)/eDP cable such as noise source 302. However, in one embodiment the value of this minimum distance is an exemplary starting guideline only and that actual measured RF noise performance may dictate otherwise (e.g., a greater or lesser minimum distance) based on mechanical and ID constraints. It will also be understood that the minimum distance to ensure sufficiently interference free operation of the multiple antennas may be selected to meet the isolation/ECC specification for MIMO performance, and that this distance may also vary depending on antenna type, frequency band, mechanical environment, etc. Such a distance may be empirically measured in one embodiment, e.g., in a laboratory during system product development. Moreover, the minimum tolerable noise interference may vary per requirements or desires of a given wireless application, and therefore the minimum separation distance from a noise source 302 and antenna element 282 may vary and be selected accordingly.
In the illustrated embodiment of
In the illustrated embodiment, antenna element 2821 is spaced by a minimum distance of one quarter wavelength at 2.4 GHz from antenna element 2822, and antenna element 2822 is spaced by a minimum distance of one quarter wavelength at 2.4 GHz from antenna element 2823. Thus, each of antenna elements 2821 to 2823 are spaced by a large enough distance from each of the other antenna elements 282 to ensure sufficient antenna isolation from each other. However, as shown in
Next, dynamic MIMO configuration logic 297 executing on one or more baseband processing devices of radio module 280 may use the device identity determined in step 602 to determine whether to activate dynamic MIMO antenna reconfiguration capability. For example in steps 604 and 606, the queried system device identity of step 602 (e.g., device identifier number or other type of code) may be compared to a previously-stored look up table or other stored dynamic MIMO configuration indicator information that contains a list of particular system device identifies that require activation of dynamic MIMO antenna reconfiguration capability. Alternatively, such a look up table may contain a correlation between particular system device identifies and an indication of whether or not to activate dynamic MIMO antenna reconfiguration capability for each system device identity, e.g., such as illustrated in the exemplary lookup table of Table 1 below. In such an alternative embodiment, it is possible that more than two respective activation codes may be associated with more than two different respective system configurations having differing numbers of multiple antenna elements and/or noise source characteristics that are to be addressed using different dynamic MIMO reconfiguration settings and different subsets of active multiple antenna elements for different wireless bands. In any event, suitable dynamic MIMO configuration indicator information may be created during system design and/or fabrication and pre-stored in applicable non-volatile memory of system 200 for later retrieval by dynamic MIMO configuration logic 297 during execution of methodology 600.
In any case, activation of dynamic MIMO reconfiguration feature capability may be indicated for a particular system configuration such as illustrated in
If it is determined in step 606 that the queried system device identity of step 602 does not match a previously stored system device identity that requires activation of dynamic MIMO antenna reconfiguration capability, then methodology 600 terminates in step 608 where dynamic MIMO antenna reconfiguration is not activated, and normal radio module operation is enabled to drive all available MIMO antenna elements for all frequency bands, e.g., using all three antennas for both Wi-Fi 3×3 2.4 GHz and Wi-Fi 3×3 5 GHz operation. However, if in step 606 it is determined that the queried system device identity of step 602 matches a previously stored system device identity that requires activation of dynamic MIMO antenna reconfiguration capability such as system 200 of
Next in step 614, it is determined if the real time currently used wireless communication band is an RF band that is substantially non-sensitive to RF interference from noise sources (e.g., such as a 5 GHz frequency band). If so, then methodology 600 proceeds to step 618 where all available MIMO antenna elements of system 200 are driven by radio module 280, e.g., using all three antennas 282 of
It will be understood that the illustrated steps of methodology 600 are exemplary only, and that any other combination of additional, fewer and/or alternative steps may be employed that is suitable to configure and/or reconfigure MIMO antenna elements of an information handling system according to particular RF interference characteristics of a given information handling system within which a radio module operates. It will also be understood that methodology 600 may be employed to enable RF transmission and reception simultaneously for connected antenna elements of different RF chains.
It will also be understood that one or more of the tasks, functions, or methodologies described herein (e.g., including those described herein for components 108, 110, 112, etc.) may be implemented by circuitry and/or by a computer program of instructions (e.g., computer readable code such as firmware code or software code) embodied in a non-transitory tangible computer readable medium (e.g., optical disk, magnetic disk, non-volatile memory device, etc.), in which the computer program comprising instructions are configured when executed (e.g., executed on a processing device of an information handling system such as CPU, controller, microcontroller, processor, microprocessor, FPGA, ASIC, or other suitable processing device) to perform one or more steps of the methodologies disclosed herein. A computer program of instructions may be stored in or on the non-transitory computer-readable medium accessible by an information handling system for instructing the information handling system to execute the computer program of instructions. The computer program of instructions may include an ordered listing of executable instructions for implementing logical functions in the information handling system. The executable instructions may comprise a plurality of code segments operable to instruct the information handling system to perform the methodology disclosed herein. It will also be understood that one or more steps of the present methodologies may be employed in one or more code segments of the computer program. For example, a code segment executed by the information handling system may include one or more steps of the disclosed methodologies.
For purposes of this disclosure, an information handling system may include any instrumentality or aggregate of instrumentalities operable to compute, classify, process, transmit, receive, retrieve, originate, switch, store, display, manifest, detect, record, reproduce, handle, or utilize any form of information, intelligence, or data for business, scientific, control, entertainment, or other purposes. For example, an information handling system may be a personal computer, a PDA, a consumer electronic device, a network storage device, or any other suitable device and may vary in size, shape, performance, functionality, and price. The information handling system may include memory, one or more processing resources such as a central processing unit (CPU) or hardware or software control logic. Additional components of the information handling system may include one or more storage devices, one or more communications ports for communicating with external devices as well as various input and output (I/O) devices, such as a keyboard, a mouse, and a video display. The information handling system may also include one or more buses operable to transmit communications between the various hardware components.
While the invention may be adaptable to various modifications and alternative forms, specific embodiments have been shown by way of example and described herein. However, it should be understood that the invention is not intended to be limited to the particular forms disclosed. Rather, the invention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. Moreover, the different aspects of the disclosed systems and methods may be utilized in various combinations and/or independently. Thus the invention is not limited to only those combinations shown herein, but rather may include other combinations.
Claims
1. A mobile information handling system, comprising:
- a host processing device;
- at least two available multiple input, multiple output (MIMO) antenna elements; and
- at least one radio module coupled between the host processing device and each of the available MIMO antenna elements, the radio module including at least one processing device and being configured to at least one of: process and combine separate RF signals received in at least a common first frequency band from each of the available MIMO antenna elements to produce incoming data provided to the host processing device, or process outgoing data provided from the host processing device to produce and transmit separate RF signals in the common first frequency band from each of the available MIMO antenna elements, or a combination thereof;
- where the processing device of the radio module is configured to determine an identity of a system chassis configuration of the mobile information handling system, and to then respond in real time to this determined identity by at least one of: dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring a subset of the available MIMO antenna elements that are actively utilized to receive separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are received by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are received by all of the available MIMO antenna elements; or dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring a subset of the available MIMO antenna elements that are actively utilized to transmit separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are transmitted by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are transmitted by all of the available MIMO antenna elements; or a combination thereof.
2. The mobile information handling system of claim 1, further comprising at least one RF noise source; where each of the multiple MIMO antenna elements is positioned at a different distance from the RF noise source such that the RF noise source is positioned closer to a first one of the multiple MIMO antenna elements than to any other of the multiple MIMO antenna elements; where the RF noise source has a configuration that produces RF noise in the common first frequency band when the mobile information handling system is operating; where the system has a system chassis configuration that has radio frequency (RF) interference characteristics associated with the identity of the system chassis configuration for the common first frequency band, the RF interference characteristics for the common first frequency band including the position of the RF noise source for the common first frequency band relative to the first MIMO antenna element; and where the processing device of the radio module is configured to:
- dynamically configure, dynamically reconfigure, or dynamically configure and reconfigure a subset of the available MIMO antenna elements that are utilized to receive separate RF signals in the common first frequency band based on the interference characteristics of the system chassis configuration for the common first frequency band and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are received by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are received by all of the available MIMO antenna elements; or
- dynamically configure, dynamically reconfigure, or dynamically configure and reconfigure a subset of the available MIMO antenna elements that are utilized to transmit separate RF signals in a common first frequency band based on the interference characteristics of the system chassis configuration for the common first frequency band and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are transmitted by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are transmitted by all of the available MIMO antenna elements; or
- a combination thereof.
3. The mobile information handling system of claim 2, where the RF noise source has a configuration that produces substantially no RF noise in a different common second frequency band when the mobile information handling system is operating such that the system chassis configuration has different radio frequency (RF) interference characteristics associated with the identity of the system chassis configuration for the common second frequency band, the RF interference characteristics for the common second frequency band including no RF noise source for the common second frequency band positioned relative to any of the MIMO antenna elements; and where the processing device of the radio module is configured to:
- dynamically configure, dynamically reconfigure, or dynamically configure and reconfigure all of the available MIMO antenna elements to be actively utilized to receive separate RF signals in the common second frequency band based on the interference characteristics of the system chassis configuration for the common second frequency band and based on the identity of the common second RF frequency band to achieve substantially the same amount of RF interference imparted to RF signals of the common second frequency band that are received by all of the available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common second frequency band when the RF signals of the common second frequency band are received by any subset of the available MIMO antenna elements; or
- dynamically configure, dynamically reconfigure, or dynamically configure and reconfigure all of the available MIMO antenna elements to be actively utilized to transmit separate RF signals in the common second frequency band based on the interference characteristics of the system chassis configuration for the common second frequency band and based on the identity of the common second RF frequency band to achieve substantially the same amount of RF interference imparted to RF signals of the common second frequency band that are transmitted by all of the available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common second frequency band when the RF signals of the common second frequency band are transmitted by any subset of the available MIMO antenna elements; or
- a combination thereof.
4. The mobile information handling system of claim 3, where the common first frequency band is 2.4 GHz Wi-Fi band; and where the common second frequency band is 5 GHz Wi-Fi band.
5. The mobile information handling system of claim 1, where the at least one processing device of the radio module is further configured to:
- process and combine separate RF signals received in a different common second frequency band from each of the available MIMO antenna elements to at least one of: produce incoming data provided to the host processing device, or process outgoing data provided from the host processing device to produce and transmit separate RF signals in the common second frequency band from each of the available MIMO antenna elements, or a combination thereof; and
- respond in real time to the determined identity of the system chassis configuration by: dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring all of the available MIMO antenna elements to be actively utilized to receive separate RF signals in the common second frequency band based on the determined identity of the system chassis configuration and based on the identity of the common second RF frequency band; or dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring all of the available MIMO antenna elements to be actively utilized to transmit separate RF signals in the common second frequency band based on the determined identity of the system chassis configuration and based on the identity of the common second RF frequency band; or a combination thereof.
6. The mobile information handling system of claim 5, where the common first frequency band is 2.4 GHz Wi-Fi band; and where the common second frequency band is 5 GHz Wi-Fi band.
7. The mobile information handling system of claim 5, where the amount of RF interference imparted to RF signals of the common second frequency band when received by any subset of the available MIMO antenna elements is substantially the same as the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are received by all of the available MIMO antenna elements; or where the amount of RF interference imparted to RF signals of the common second frequency band when transmitted by any subset of the available MIMO antenna elements is substantially the same as the amount of RF interference imparted to RF signals of the common second frequency band when the RF signals of the common first frequency band are transmitted by all of the available MIMO antenna elements; or a combination thereof.
8. The mobile information handling system of claim 1, where a system chassis configuration of the mobile information handling system comprises:
- a lid component hingeably coupled to a base component by one or more hinges at a hinge line, a hinge cavity defined in at least one of the base component or lid component;
- where each of the MIMO antenna elements and each of the hinges are contained in the hinge cavity, the MIMO antenna elements being disposed in spaced relationship relative to each other within the hinge cavity.
9. The mobile information handling system of claim 8, where the radio module and host processing device are contained within the base component; where the lid component includes an integral display component coupled to the host processing device by an embedded display port (eDP) component that is contained within the hinge cavity; where each of the multiple MIMO antenna elements is positioned at a different distance from the eDP component such that eDP component is positioned closer to a first one of the multiple MIMO antenna elements than to any other of the multiple MIMO antenna elements; where the eDP component has a configuration that produces RF noise in the common first frequency band when the mobile information handling system is operating to transmit signals across the eDP component; and where the processing device of the radio module is configured to determine the identity of the system chassis configuration of the mobile information handling system, and to then respond in real time to this determined identity by at least one of:
- dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring a subset of the available MIMO antenna elements that does not include the first MIMO antenna element to receive separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band; or
- dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring a subset of the available MIMO antenna elements that does not include the first MIMO antenna element to transmit separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band; or
- a combination thereof.
10. The mobile information handling system of claim 9, where the eDP component having a configuration that produces substantially no RF noise in a different common second frequency band when the mobile information handling system is operating to transmit signals across the eDP component; and where the processing device of the radio module is configured to determine the identity of the system chassis configuration of the mobile information handling system, and to then respond in real time to this determined identity by at least one of:
- dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring all of the available MIMO antenna elements including the MIMO antenna element that is positioned closest to the eDP component to be actively utilized to receive separate RF signals in the common second frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band; or
- dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring all of the available MIMO antenna elements to be actively utilized to transmit separate RF signals in the common second frequency band based on the interference characteristics of the system chassis configuration for the common second frequency band and based on the identity of the common second RF frequency band; or
- a combination thereof.
11. The mobile information handling system of claim 10, where the common first frequency band is 2.4 GHz Wi-Fi band; where the common second frequency band is 5 GHz Wi-Fi band; where the mobile information handling system comprises at least three MIMO antennas within the hinge cavity.
12. A method of operating a mobile information handling system, comprising using at least one processing device of a radio module of the information handling system to:
- process and combine separate RF signals received in at least a common first frequency band from each of at least two available multiple input, multiple output (MIMO) antenna elements to at least one of: produce incoming data provided to a host processing device of the information handling system, or process outgoing data provided from the host processing device to produce and transmit separate RF signals in the common first frequency band from each of the available MIMO antenna elements, or a combination thereof;
- determine an identity of a system chassis configuration of the mobile information handling system; and
- then respond in real time to the determined identity by at least one of: dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring a subset of the available MIMO antenna elements that are actively utilized to receive separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are received by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are received by all of the available MIMO antenna elements; or dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring a subset of the available MIMO antenna elements that are actively utilized to transmit separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are transmitted by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are transmitted by all of the available MIMO antenna elements; or a combination thereof.
13. The method of claim 12, where the information handling system further comprises at least one RF noise source; where each of the multiple MIMO antenna elements is positioned at a different distance from the RF noise source such that the RF noise source is positioned closer to a first one of the multiple MIMO antenna elements than to any other of the multiple MIMO antenna elements; where the RF noise source has a configuration that produces RF noise in the common first frequency band when the mobile information handling system is operating; where the system has a system chassis configuration that has radio frequency (RF) interference characteristics associated with the identity of the system chassis configuration for the common first frequency band, the RF interference characteristics for the common first frequency band including the position of the RF noise source for the common first frequency band relative to the first MIMO antenna element; and where the method further comprises:
- operating the mobile information handling system to cause the noise source to produce noise in the common first frequency band; and
- using the processing device of the radio module to: dynamically configure, dynamically reconfigure, or dynamically configure and reconfigure a subset of the available MIMO antenna elements to receive separate RF signals in the common first frequency band based on the interference characteristics of the system chassis configuration for the common first frequency band and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are received by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are received by all of the available MIMO antenna elements; or dynamically configure, dynamically reconfigure, or dynamically configure and reconfigure a subset of the available MIMO antenna elements to transmit separate RF signals in a common first frequency band based on the interference characteristics of the system chassis configuration for the common first frequency band and based on the identity of the common first RF frequency band to achieve a reduction in the amount of RF interference imparted to RF signals of the common first frequency band that are transmitted by the subset of available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common first frequency band when the RF signals of the common first frequency band are transmitted by all of the available MIMO antenna elements; or a combination thereof.
14. The method of claim 13, where the RF noise source has a configuration that produces substantially no RF noise in a different common second frequency band when the mobile information handling system is operating such that the system chassis configuration has different radio frequency (RF) interference characteristics associated with the identity of the system chassis configuration for the common second frequency band, the RF interference characteristics for the common second frequency band including no RF noise source for the common second frequency band positioned relative to any of the MIMO antenna elements; and where the method further comprises operating the processing device of the radio module to:
- dynamically configure, dynamically reconfigure, or dynamically configure and reconfigure all of the available MIMO antenna elements to receive separate RF signals in the common second frequency band based on the interference characteristics of the system chassis configuration for the common second frequency band and based on the identity of the common second RF frequency band to achieve substantially the same amount of RF interference imparted to RF signals of the common second frequency band that are received by all of the available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common second frequency band when the RF signals of the common second frequency band are received by any subset of the available MIMO antenna elements; or
- dynamically configure, dynamically reconfigure, or dynamically configure and reconfigure all of the available MIMO antenna elements to transmit separate RF signals in the common second frequency band based on the interference characteristics of the system chassis configuration for the common second frequency band and based on the identity of the common second RF frequency band to achieve substantially the same amount of RF interference imparted to RF signals of the common second frequency band that are transmitted by all of the available MIMO antenna elements as compared to the amount of RF interference imparted to RF signals of the common second frequency band when the RF signals of the common second frequency band are transmitted by any subset of the available MIMO antenna elements; or
- a combination thereof.
15. The method of claim 14, where the common first frequency band is 2.4 GHz Wi-Fi band; and where the common second frequency band is 5 GHz Wi-Fi band.
16. The method of claim 12, further comprising using the at least one processing device of the radio module to:
- process and combine separate RF signals received in a different common second frequency band from each of the available MIMO antenna elements to at least one of: produce incoming data provided to the host processing device, or process outgoing data provided from the host processing device to produce and transmit separate RF signals in the common second frequency band from each of the available MIMO antenna elements, or a combination thereof; and
- respond in real time to the determined identity of the system chassis configuration by: dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring all of the available MIMO antenna elements to be actively utilized to receive separate RF signals in the common second frequency band based on the determined identity of the system chassis configuration and based on the identity of the common second RF frequency band; or dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring all of the available MIMO antenna elements to be actively utilized to transmit separate RF signals in the common second frequency band based on the determined identity of the system chassis configuration and based on the identity of the common second RF frequency band; or a combination thereof.
17. The method of claim 16, where the common first frequency band is 2.4 GHz Wi-Fi band; and where the common second frequency band is 5 GHz Wi-Fi band.
18. The method of claim 12, where a system chassis configuration of the mobile information handling system comprises:
- a lid component hingeably coupled to a base component by one or more hinges at a hinge line, a hinge cavity defined in at least one of the base component or lid component;
- where each of the MIMO antenna elements and each of the hinges are contained in the hinge cavity, the MIMO antenna elements being disposed in spaced relationship relative to each other within the hinge cavity;
- where the radio module and host processing device are contained within the base component;
- where the lid component includes an integral display component coupled to the host processing device by an embedded display port (eDP) component that is contained within the hinge cavity; where each of the multiple MIMO antenna elements is positioned at a different distance from the eDP component such that eDP component is positioned closer to a first one of the multiple MIMO antenna elements than to any other of the multiple MIMO antenna elements; and
- where the method further comprises transmitting signals across the eDP component to produce RF noise in the common first frequency band while the mobile information handling system is operating; using the processing device of the radio module to determine the identity of the system chassis configuration of the mobile information handling system; and then using the processing device of the radio module to then respond in real time to this determined identity by at least one of: dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring a subset of the available MIMO antenna elements that does not include the first MIMO antenna element to receive separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band; or dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring a subset of the available MIMO antenna elements that does not include the first MIMO antenna element to transmit separate RF signals in the common first frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band; or a combination thereof.
19. The method of claim 18, further comprising transmitting signals across the eDP component to produce substantially no RF noise in a different common second frequency band; using the processing device of the radio module to determine the identity of the system chassis configuration of the mobile information handling system; and then using the processing device of the radio module to respond in real time to this determined identity by at least one of:
- dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring all of the available MIMO antenna elements including the MIMO antenna element that is positioned closest to the eDP component to be actively utilized to receive separate RF signals in the common second frequency band based on the determined identity of the system chassis configuration and based on the identity of the common first RF frequency band; or
- dynamically configuring, dynamically reconfiguring, or dynamically configuring and reconfiguring all of the available MIMO antenna elements to be actively utilized to transmit separate RF signals in the common second frequency band based on the interference characteristics of the system chassis configuration for the common second frequency band and based on the identity of the common second RF frequency band; or
- a combination thereof.
20. The method of claim 19, where the common first frequency band is 2.4 GHz Wi-Fi band; where the common second frequency band is 5 GHz Wi-Fi band; where the mobile information handling system comprises at least three MIMO antennas within the hinge cavity.
Type: Application
Filed: May 20, 2015
Publication Date: Nov 24, 2016
Inventors: Liam Prendergast (Limerick), Benny Bologna (Austin, TX)
Application Number: 14/717,469