Patent application number | Description | Published |
20080275705 | Battery Tester with Wireless Voice Status Messages - Methods and systems are disclosed for providing wireless data transfer and voice messages in a voltage measurement device. In some embodiments, the methods and systems dynamically construct voice messages that substantially correspond to text messages displayed on a display of the measurement device. The voice messages may be assembled from words and phrases that have been prerecorded and stored in a voice module of the measurement device. A wireless communication module transmits the voice messages from the voice module to a wireless receiver that may be worn or carried by the operator. The wireless communication module also facilitates wireless transfer of data from the measurement device to a computer. Such an arrangement allows an operator to conduct tests in noisy, cramp, and/or hazardous environments without having to divert his/her eyes to see or strain his/her ears to hear the measurement device. | 11-06-2008 |
20120078550 | System And Method For Displaying Battery String Cell Data In Polar Coordinate Graphical Form - In accordance with an aspect of the present disclosure, battery string cell data obtained by a battery monitor monitoring the battery string is transmitted to a computer by the battery monitor. The computer has a display coupled to it. The computer displays the battery string cell data for each battery string in graphical form in a polar coordinate graphical image with data for a plurality of battery strings being displayed simultaneously, each in its own polar coordinate graphical image. | 03-29-2012 |
20120119745 | BATTERY MONITOR WITH CORRECTION FOR INTERNAL OHMIC MEASUREMENTS OF BATTERY CELLS IN PARALLEL CONNECTED BATTERY STRINGS - A battery monitor determines an internal resistance of a battery cell of a battery having parallel connected battery strings which accounts for errors introduced by the parallel connected battery strings. When determining the internal resistance of a battery cell, the battery monitor determines a baseline intercell resistance of an intercell connecting the negative terminal of the battery cell to the positive terminal of an adjacent battery. The battery monitor then applies a momentary load across the battery cell and immediately prior to releasing the load, measures the voltage across the battery cell (loaded voltage) and the voltage across the intercell. The battery monitor then calculates the current flowing through the intercell (intercell current) by dividing the measured voltage across the intercell by the determined intercell resistance. Immediately after releasing the load, the battery monitor measures the voltage across the battery cell (recovered voltage) and determines the battery cell internal resistance by dividing the difference between the recovered voltage and the loaded voltage by the intercell current. | 05-17-2012 |
20130021037 | WIRELESS PORTABLE BATTERY CAPACITY TEST SYSTEM - A battery capacity test system includes one or more wireless battery capacity test (“BCT”) sense modules, a continuous load unit, and a wireless data collection unit. The wireless data collection unit interfaces with a computer. During a battery capacity test, the wireless BCT sense module (or modules) continuously monitors the voltage of the battery cell (or cells) to which it is connected. In an aspect, it also continuously monitors the temperature of the battery cell (or cells) and intercell voltage (or voltages) across an intercell connector (or connectors). Each wireless BCT sense module wirelessly transmits the voltage and temperature data it collects to the wireless data collection unit. | 01-24-2013 |
20130302655 | Ultrasonic Electrolyte Sensor - A system is disclosed for monitoring an electrolyte level in a battery cell and generating an indication of a fault condition when the electrolyte level drops below a predetermined acceptable level. The system may make use of a controller, an ultrasonic transmit circuit for transmitting an ultrasonic signal into an interior area of the battery cell, and an ultrasonic receive circuit for receiving the ultrasonic signal after it has been reflected from the interior area of the battery cell. The controller may use the reflected ultrasonic signal and a predetermined calibration signal representing the predetermined acceptable level of the electrolyte to determine when the electrolyte level has dropped below the predetermined acceptable level. | 11-14-2013 |
Patent application number | Description | Published |
20090290531 | LARGE PACKET CONCATENATION IN SATELLITE COMMUNICATION SYSTEM - Upstream information arriving through a gateway from a user terminal in a satellite link subject to propagation delay is efficiently scheduled through a modified Demand Assigned Multiple Access (DAMA) algorithm such that arriving data packets arriving at the software queue at the user terminal are concatenated to form a large frame for transmission to improve efficiency. A piggyback request replacing a conventional DAMA contention request for the succeeding packet is issued to request bandwidth allocation for the succeeding concatenated packet. In a specific embodiment, all packets up to the physical request limit arriving at the user terminal since a prior piggyback request or contention request are concatenated so that all currently known packets (up to that limit) are accounted for by the next piggyback request. | 11-26-2009 |
20090290532 | MAP-TRIGGERED DUMP OF PACKETS IN SATELLITE COMMUNICATION SYSTEM - Upstream information arriving through a user terminal in a satellite link is efficiently scheduled through a modified Demand Assigned Multiple Access (DAMA) algorithm such that data packets arriving at the user terminal are concatenated to form a larger frame for transmission and the concatenated packet is held in a first queue disposed ahead of a second queue, where the data in the second queue cannot be modified (typically a hardware queue), sufficient to allow the second queue to be emptied. In a specific embodiment, all packets arriving at the user terminal since a prior piggyback request are concatenated so that all currently known packets (up to a preselected limit) are accounted for by each succeeding piggyback request. Since it is desirable to concatenate all packets that arrive at the user terminal since the last piggyback request, the piggyback request according to the invention covers all currently known packets (up to the preselected limit) in the user terminal. The held-back packets are released or dumped to the second queue by a trigger operative according to a map, the map being a grant allocation schedule. This mechanism handles instances where the second queue is not able to handle all known packets. | 11-26-2009 |
20090290533 | WEB-BULK TRANSFER PREALLOCATION OF UPSTREAM RESOURCES IN A SATELLITE COMMUNICATION SYSTEM - In a data over satellite system, preallocation of upstream channel resources is provided by a scheduler at the gateway satellite modem termination system (SMTS) in response from the user terminal, wherein the user terminal detects web browser and/or bulk transfers involving large amounts of data transfer from users via the upstream channel. A type length value (TLV) field is included with data packets transmitted to the gateway SMTS, at which excess transfer capability is allocated to the user terminal in anticipation of load requirements. | 11-26-2009 |
20090290534 | UPFRONT DELAYED CONCATENATION IN SATELLITE COMMUNICATION SYSTEM - Upstream information at a user terminal in a satellite network is efficiently scheduled through a Demand Assigned Multiple Access (DAMA) algorithm that delays transmission of the first packet's bandwidth allocation request in order to allow subsequent packets to be included in the first packet's bandwidth allocation request (up-front delayed concatenation) in order to minimize delay due to the long round trip time and overhead in packet processing and packet transmission through a hardware queue. Rather than merely the size of the next packet, the size of the entire concatenated frame is communicated to the scheduler, which may be distributed between the user satellite modem and the gateway, to prepare the schedule, where the schedule is the basis of the upstream transmission of the various associated user terminals. Optimal delay is a function of traffic pattern and the scheduling delay including round-trip delay. | 11-26-2009 |