An ultrasonic system includes an ultrasonic probe and a data processing unit which is physically separate from the ultrasonic probe, runs on an operating system and has a receiving memory and a transmission memory. A real-time bus system is for data coupling of the ultrasonic probe to the memories. A probe system manages data within the ultrasonic probe, the clock inaccuracy of the probe system is at least three orders of magnitude less than the clock inaccuracy of the real-time bus system. The response time of the operating system is at least two orders of magnitude longer than the clock inaccuracy of the real-time bus system. The real-time bus system is configured to transfer transmission data and received data simultaneously by uninterrupted streaming clocked with an on average constant rate during stateless operation of the ultrasonic probe, the operation not differentiating between transmission and receiving operation.

A patient station for telemedicine enabling transmission of patient data to a remote doctor station, via a telecommunication network includes a processing unit with an operating system, a main display device, and at least one first sensor of a first type generating first patient data. The processing unit is configured to generate a first video signal or a first image from the first patient data and display the first video signal or the first image on the main display device in a first display window, capture at least one display area of the first display window to generate a captured video signal, generate an output video signal comprising the captured video signal, emulate a digital-camera peripheral, wherein the output video signal is provided as output from the emulated digital camera peripheral to the operating system as digital camera-type peripheral device output, and provide the output video signal to the doctor station via the telecommunication network.

The present embodiments relate generally to systems and methods for ultrasound imaging. The methods may involve: establishing a wireless network between an ultrasound imaging device and a display device; acquiring ultrasound image data using ultrasound acquisition parameters; transmitting the ultrasound image data from the ultrasound imaging device to the display device over the wireless network; receiving the ultrasound image data; measuring a quality of service parameter of the received ultrasound image data; determining whether the measured quality of service parameter is less than an expected quality of service parameter, the expected quality of service parameter being determined based on the ultrasound acquisition parameters used to acquire the ultrasound image data; and in response to determining that the measured quality of service parameter is less than the expected quality of service parameter, adjusting a network parameter of the wireless network to reduce network traffic on the wireless network.

An ultrasound system with a multimedia information distribution system comprising: a video processor generating a sequence of video frames of at least the ultrasound diagnostic images of a sequence of ultrasound diagnostic images; a media editor for combining the ultrasound video frames with further audio/video data to generate multimedia data; a multimedia encoder encoding the multimedia data in the form of a multimedia file; a media streaming module receiving the said multimedia file and generating a real-time stream of the sequence of multimedia data encoded in the said multimedia file; a web server allowing access to the real-time stream of the multimedia data upon request by a remote client to access the said multimedia file. A corresponding computer implemented method is also disclosed.

Provided is an ultrasound imaging apparatus for predicting fetal growth rate, including: an ultrasound probe configured to transmit ultrasound signals to a fetus and receive ultrasound echo signals reflected from the fetus; a user inputter configured to receive pregnancy information regarding a patient from a user; a communicator configured to receive, from a cloud server, fetal biometric data related to the pregnancy information regarding the patient from among fetal biometric data prestored and accumulated in the cloud server; and a controller configured to generate an ultrasound image of the fetus by using the ultrasound echo signals, measure a size of a body part of the fetus on the ultrasound image, and predict the fetal growth rate based on the measured size of the body part of the fetus and the fetal biometric data received from the cloud server.

Implementations described and claimed herein provide systems and methods for managing one or more patients. In one implementation, an imaging window is determined based on a location of a probe. A primary image cross-section for the imaging window is identified for the imaging window. At least one image is generated along the primary image cross-section using patient data captured using the probe. The at least one image is compared to an expected image contour scaffold of the primary image cross-section. The probe is commanded to fine-tune an imaging plane based on the comparison until the at least one image matches the expected image contour scaffold of the primary image cross-section.

The present embodiments relate generally to systems and methods for acquiring raw ultrasound data from an ultrasound machine using a wirelessly connected device. The systems can be configured to display ultrasound images on a display device and receive input to select the ultrasound images for which to retrieve corresponding raw ultrasound data from the ultrasound machine. A raw data buffer provided at the ultrasound machine may be capable of storing a first time duration of raw ultrasound data. An image display buffer provided at the wireless device may store: processed ultrasound image data corresponding to the raw ultrasound data stored in the raw data buffer; and previously-received processed ultrasound image data that has no corresponding raw ultrasound data stored in the raw data buffer.

Medical devices can perform a plurality of functions, such as sensing, monitoring, deriving and/or calculating various physiological statuses of a patient (e.g., blood pressure, temperature, respiration rate, etc.). Medical devices can also be used to image part or all of a patient's body, to deliver a treatment, or to manage information related to a patient's care. The present disclosure is directed at one or more devices that perform these functions using a plurality of processing circuits, wherein each processing circuit has a timing circuit with a local clock. These processing circuits can be connected via a network, and each timing circuit can communicate with at least one other timing circuit in order to detect and correct time-differences between their local clocks. In this way, multiple processing circuits can be synchronized with each other to facilitate diagnosis or treatment of a patient's condition, or other aspects of a patient's care.

A multi-user system for acquiring, generating and processing ultrasound images comprises: a plurality of ultrasound probes with a communication unit for transmitting corresponding data to one or more processing units also with a communication unit; display and/or user interface terminals with a communication unit for transmitting to and receiving data from said processing units and/or said probes; a communication network connecting together the communication units of said probes, display and/or user interface terminals and said processing units. Processing units are configured to receive scanning signals detected by said probes and process said signals to generate ultrasound images and optionally process said ultrasound images and to transmit said images and/or outputs of said processing to said display and/or user interface terminals. Probes and/or processing units are loaded programs with encoded instructions to receive data from each of said probes and to generate the corresponding images and/or to perform the corresponding processing.

In a dematerialized ultrasound system, i.e. comprising a probe for transmitting and receiving ultrasound signals and a generic processing hardware made of one or more distributed processing units, the functions relating to the processing steps for the generation and processing of the images are in the form of software programs that encode instructions for the aforementioned generic hardware which make it capable of executing said processing steps. In order to make the computational and data interchange burden less heavy between the units of the distributed architecture of the system and to make the distribution of processing steps more flexible between one or more of the components of the distributed system, the programs are created under form of applications included in containers managed by a container management engine.