Abstract: A trans-cranial Focused Ultrasound System (tFUS) apparatus employs an ultrasonic stimulation beam that is guided by ultrasonic imaging or optical imaging to optimize a response of a subject during a procedure. The disclosed tFUS apparatus is operable without requiring either an MRI or a CT scan. The use of multiple transducers or transducer elements, including contralateral transducers, the use of ultrasonic and/or optical harmonics, the use of temporal windows, the use of a head atlas, motion tracking, LiDAR, and the use of aberration correction parameters may all be employed individually or in combination.

Abstract: Method for scanning for second object on or within first object starts by receiving information on first object and second object. Task lists are generated that include at least one task action based on information on first object and second object. Based on task lists, beamer is then signaled to generate and send first signal to first probe unit to perform first beam firing. Receiver processes first data signal from first probe unit that is then analyzed to determine if first object is identified using processed first data signal. Upon determination that first object is identified, based on task list, beamer is signaled to generate and send second signal to second probe unit to perform second beam firing. Receiver processes second data signal from second probe unit that is then analyzed to determine if second object is identified using processed second data signal. Other embodiments are described.

Abstract: Method for scanning for second object on or within first object starts by receiving information on first object and second object. Task lists are generated that include at least one task action based on information on first object and second object. Based on task lists, beamer is then signaled to generate and send first signal to first probe unit to perform first beam firing. Receiver processes first data signal from first probe unit that is then analyzed to determine if first object is identified using processed first data signal. Upon determination that first object is identified, based on task list, beamer is signaled to generate and send second signal to second probe unit to perform second beam firing. Receiver processes second data signal from second probe unit that is then analyzed to determine if second object is identified using processed second data signal. Other embodiments are described.

Abstract: Method for scanning for second object on or within first object starts by receiving information on first object and second object. Task lists are generated that include at least one task action based on information on first object and second object. Based on task lists, beamer is then signaled to generate and send first signal to first probe unit to perform first beam firing. Receiver processes first data signal from first probe unit that is then analyzed to determine if first object is identified using processed first data signal. Upon determination that first object is identified, based on task list, beamer is signaled to generate and send second signal to second probe unit to perform second beam firing. Receiver processes second data signal from second probe unit that is then analyzed to determine if second object is identified using processed second data signal. Other embodiments are described.

Abstract: Method for scanning for second object on or within first object starts by receiving information on first object and second object. Task lists are generated that include at least one task action based on information on first object and second object. Based on task lists, beamer is then signaled to generate and send first signal to first probe unit to perform first beam firing. Receiver processes first data signal from first probe unit that is then analyzed to determine if first object is identified using processed first data signal. Upon determination that first object is identified, based on task list, beamer is signaled to generate and send second signal to second probe unit to perform second beam firing. Receiver processes second data signal from second probe unit that is then analyzed to determine if second object is identified using processed second data signal. Other embodiments are described.

Abstract: Method for scanning for second object on or within first object starts by receiving information on first object and second object. Task lists are generated that include at least one task action based on information on first object and second object. Based on task lists, beamer is then signaled to generate and send first signal to first probe unit to perform first beam firing. Receiver processes first data signal from first probe unit that is then analyzed to determine if first object is identified using processed first data signal. Upon determination that first object is identified, based on task list, beamer is signaled to generate and send second signal to second probe unit to perform second beam firing. Receiver processes second data signal from second probe unit that is then analyzed to determine if second object is identified using processed second data signal. Other embodiments are described.

Abstract: Method for scanning for second object on or within first object starts by receiving information on first object and second object. Task lists are generated that include at least one task action based on information on first object and second object. Based on task lists, beamer is then signaled to generate and send first signal to first probe unit to perform first beam firing. Receiver processes first data signal from first probe unit that is then analyzed to determine if first object is identified using processed first data signal. Upon determination that first object is identified, based on task list, beamer is signaled to generate and send second signal to second probe unit to perform second beam firing. Receiver processes second data signal from second probe unit that is then analyzed to determine if second object is identified using processed second data signal. Other embodiments are described.

Abstract: Apparatus for adaptively scheduling ultrasound device actions includes a probe interface, a beamer, a receiver, a processor, and a memory. The probe interface may interface with probe units to transmit signals generated by the beamer to the probe units and to receive data signals from the probe units. The processor may be coupled to the probe interface, the beamer, and the receiver. The memory may store instructions, which when executed by the processor, causes the processor to generate a task list and to signal to the beamer to generate signals to the probe units associated with the plurality of task actions. The task list may include a plurality of task actions associated with probe units, and the processor may signal to the beamer in accordance with a timed beam firing sequence. Other embodiments are also described.

Abstract: A method of scanning for an object using an adaptive scheduler starts with an electronic circuit (EC) receiving information associated with the object. A task list is then generated by the EC that includes at least one task action based on the information associated with the object. The at least one task action includes a beam firing required for the object to be scanned. The EC may signal based on the task list to a beamer to generate and send a signal to a probe unit to perform the beam firing. A receiver may receive and process a data signal from the probe unit and send the processed data signals to the EC. The EC may then analyze the processed data signal to determine if the object is identified using the processed data signal. Other embodiments are also described.

Abstract: Apparatus for real-time execution of ultrasound system actions includes processor and memory to store instructions. Execution of the instructions causes processor to receive a task list including task actions that include next task action in task list. Next task action includes task instructions. Processor determines whether next task instruction in next task action is a timed instruction that includes a timestamp field having a time value indicating a time at which next task action is to be executed, and a hardware-enable field indicating hardware elements required to be available before execution of timed instruction. If next task instruction is not a timed instruction, processor may execute next task instruction. If next task instruction is timed instruction, processor determines whether time value has expired. If time value has expired, processor signals an error has occurred, and if time value has not expired, processor waits for time value. Other embodiments are described.

Abstract: Apparatus for adaptively scheduling ultrasound device actions includes a probe interface, a beamer, a receiver, a processor, and a memory. The probe interface may interface with probe units to transmit signals generated by the beamer to the probe units and to receive data signals from the probe units. The processor may be coupled to the probe interface, the beamer, and the receiver. The memory may store instructions, which when executed by the processor, causes the processor to generate a task list and to signal to the beamer to generate signals to the probe units associated with the plurality of task actions. The task list may include a plurality of task actions associated with probe units, and the processor may signal to the beamer in accordance with a timed beam firing sequence. Other embodiments are also described.

Abstract: Apparatus for adaptively scheduling ultrasound device actions includes a probe interface, a beamer, a receiver, a processor, and a memory. The probe interface may interface with probe units to transmit signals generated by the beamer to the probe units and to receive data signals from the probe units. The processor may be coupled to the probe interface, the beamer, and the receiver. The memory may store instructions, which when executed by the processor, causes the processor to generate a task list that includes a timed beam firing sequence and to signal to the beamer to generate signals to the probe units associated with the plurality of task actions. The task list may include a plurality of task actions associated with probe units, and the processor may signal to the beamer in accordance with the timed beam firing sequence. Other embodiments are also described.

Abstract: A method of adaptively scheduling ultrasound device actions starts with an electronic circuit included in an adaptive scheduler selecting a next task in a task list. The task list may include tasks scheduled to be performed by an ultrasound system. Each of the tasks may include a plurality of task actions. The electronic circuit may then determine if a task action included in the next task can start. This determination may include determining if the task action can be completed without interfering with a start of a higher priority task in the task list. When the electronic circuit determines that the next task action can start, the electronic circuit may signal to a beam associated with the task action to start and perform the task action. Other embodiments are also disclosed.

Abstract: Apparatus to control and execute ultrasound system actions includes API that includes API procedure, processor coupled to API, adaptive scheduler, and memory. Adaptive scheduler includes beamer to generate signals, probe interface to transmit the signals to at least one probe unit and to receive signals from the at least one probe unit, and receiver to receive and process the signals received from the probe interface. Memory stores instructions, which when executed, causes processor to receive task list including task actions. Processor may execute API procedure to generate scan specification that is a data structure that includes task list. Processor may execute API procedure to identify at least one of: a probe required to perform the task actions, a beam required to perform the task actions and requirements and parameters associated with the beam, or a format of a beam firing result. Other embodiments are described.

Abstract: Method for scanning for second object on or within first object starts by receiving information on first object and second object. Task lists are generated that include at least one task action based on information on first object and second object. Based on task lists, beamer is then signaled to generate and send first signal to first probe unit to perform first beam firing. Receiver processes first data signal from first probe unit that is then analyzed to determine if first object is identified using processed first data signal. Upon determination that first object is identified, based on task list, beamer is signaled to generate and send second signal to second probe unit to perform second beam firing. Receiver processes second data signal from second probe unit that is then analyzed to determine if second object is identified using processed second data signal. Other embodiments are described.

Abstract: A method of scanning for an object using an adaptive scheduler starts with an electronic circuit (EC) receiving information associated with the object. A task list is then generated by the EC that includes at least one task action based on the information associated with the object. The at least one task action includes a beam firing required for the object to be scanned. The EC may signal based on the task list to a beamer to generate and send a signal to a probe unit to perform the beam firing. A receiver may receive and process a data signal from the probe unit and send the processed data signals to the EC. The EC may then analyze the processed data signal to determine if the object is identified using the processed data signal. Other embodiments are also described.

Abstract: A method of adaptively scheduling ultrasound device actions starts with an electronic circuit included in an adaptive scheduler selecting a next task in a task list. The task list may include tasks scheduled to be performed by an ultrasound system. Each of the tasks may include a plurality of task actions. The electronic circuit may then determine if a task action included in the next task can start. This determination may include determining if the task action can be completed without interfering with a start of a higher priority task in the task list. When the electronic circuit determines that the next task action can start, the electronic circuit may signal to a beam associated with the task action to start and perform the task action. Other embodiments are also disclosed.

Abstract: Apparatus for adaptively scheduling ultrasound device actions includes a probe interface, a beamer, a receiver, a processor, and a memory. The probe interface may interface with probe units to transmit signals generated by the beamer to the probe units and to receive data signals from the probe units. The processor may be coupled to the probe interface, the beamer, and the receiver. The memory may store instructions, which when executed by the processor, causes the processor to generate a task list that includes a timed beam firing sequence and to signal to the beamer to generate signals to the probe units associated with the plurality of task actions. The task list may include a plurality of task actions associated with probe units, and the processor may signal to the beamer in accordance with the timed beam firing sequence. Other embodiments are also described.

Abstract: Apparatus for real-time execution of ultrasound system actions includes processor and memory to store instructions. Execution of the instructions causes processor to receive a task list including task actions that include next task action in task list. Next task action includes task instructions. Processor determines whether next task instruction in next task action is a timed instruction that includes a timestamp field having a time value indicating a time at which next task action is to be executed, and a hardware-enable field indicating hardware elements required to be available before execution of timed instruction. If next task instruction is not a timed instruction, processor may execute next task instruction. If next task instruction is timed instruction, processor determines whether time value has expired. If time value has expired, processor signals an error has occurred, and if time value has not expired, processor waits for time value. Other embodiments are described.

Abstract: Apparatus to control and execute ultrasound system actions includes API that includes API procedure, processor coupled to API, adaptive scheduler, and memory. Adaptive scheduler includes beamer to generate signals, probe interface to transmit the signals to at least one probe unit and to receive signals from the at least one probe unit, and receiver to receive and process the signals received from the probe interface. Memory stores instructions, which when executed, causes processor to receive task list including task actions. Processor may execute API procedure to generate scan specification that is a data structure that includes task list. Processor may execute API procedure to identify at least one of: a probe required to perform the task actions, a beam required to perform the task actions and requirements and parameters associated with the beam, or a format of a beam firing result. Other embodiments are described.