The invention relates generally to hand-held control instruments and control stations. In particular, the invention relates to ergonomic and modular instruments that can be configured for sundry operations while reducing operator fatigue.
Gun operators in military training or combat situations operate individual consoles to actuate their weapons from a control station. Conventional such stations must be custom configured for particular missions. Additionally, attention demands for a variety of parameters to be controlled, along with non-optimal physiognomic configuration, can induce operator fatigue.
Conventional hand-held control instruments and associated control stations yield disadvantages addressed by various exemplary embodiments of the present invention. In particular, various exemplary embodiments provide an ergonomic control instrument for an operator's hand to be disposable on a platform and communicate with a processor. The instrument includes a base for mounting to the platform, a pistol-grip handle disposed on the base to tilt from perpendicular to the platform, a head unit disposed on the handle, a deck within the head unit connecting to the handle, and a plurality of input devices disposed on at least one of the head unit and the handle, each device of the plurality for receiving a command from the operator's hand.
Additionally, various exemplary embodiments provide an ergonomic control station for an operator, with the station including a platform in front of the operator, a first hand-held instrument mountable to the platform, a second hand-held instrument mountable to the platform, and a processor having a plurality of connections to the first and second pluralities of input devices.
These and various other features and aspects of various exemplary embodiments will be readily understood with reference to the following detailed description taken in conjunction with the accompanying drawings, in which like or similar numbers are used throughout, and in which:
In the following detailed description of exemplary embodiments of the invention, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration specific exemplary embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. Other embodiments may be utilized, and logical, mechanical, and other changes may be made without departing from the spirit or scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims.
The configurable weapons control station benefits from (1) ergonomic disposition of hand-held instruments and associated appendage (i.e., thumb and finger) actuation, (2) component modularity for parts substitution or rearrangement, and (3) configurability to facilitate additional or alternate commands to be incorporated in the instrument in support of alternate mission scenarios. Various exemplary embodiments separately address the control station with attendant processor and the hand-held instrument that represents the controller mechanism to enable command input for the operator with reduced fatigue.
The operator's left hand and fingers wrap around to grip the port handle 430. The port base 440 is configured to tilt the port handle 430 from perpendicular to the platform 240 towards starboard (sloping inward towards the operator's torso) to reduce operator fatigue. The operator can also operate a port trigger assembly 460 with his (or her) left forefinger. The trigger assembly 460 is suspended from the port head 410 and includes a trigger 462, a guard 464 and a pressure switch 466 within the handle 430. The base 440 attaches to the handle 430 from the fore by a screw 470.
A starboard pistol-grip handle 530 secures an internal deck by screws to support the starboard head 510, and attaches to a base 540 secured by a pair of bolts 545 with accompanying nuts. The starboard base 540 is configured to tilt the starboard handle 530 from perpendicular to the platform 240 towards port (sloping inward towards the operator's torso) to reduce operator fatigue. A coaxial cable 550 connects to the base 540 via a coaxial connector 555.
The operator can also actuate a starboard trigger assembly 560 with the operator's right forefinger. The trigger assembly 560 is suspended from the starboard head 510 and includes a trigger 562, a guard 564 and a pressure switch 566 within the handle 530. The base 540 attaches to the handle 530 from the fore by a screw 570. The operator's right hand and fingers wrap around to grip the starboard handle 530 and pivotably secures an aft palm switch 580 to activate a pressure switch 585.
The handle 530 includes a grip stock 630 having a top surface 631 with a scallop 632 for receiving the trigger assembly 560, a hole 633 for receiving a hinge screw 634, a keyslot groove 635 at the bottom with adjacent side-holes 636 for receiving the screws 545. The base 540 includes a mount 640 having a forward tongue 642 and an aft tongue 644 separated by a gap 646 for inserting a bolt. The tongues 642 and 644 fit into the groove 634 to connect the handle 530 to the base 540. Screws 648 secure the coaxial cable connector 555 into the mount 640.
An internal mounting deck 660 is disposed within the head space 516 between the head shells 512 and 514 atop the grip's top surface 631. The deck 660 includes an internal mount plate 661, a pair of beveled flanges 662 that flank a slot 663. The deck 660 permits insertion of a helical spring 664, horizontal screws 665 as well as vertical screws 666 and 667. The scallop 632 and the slot 663 enable maneuverable operation of the trigger assembly 560.
For the second embodiment of fixture 230, a mount flange 750 provides an upper surface on which the base 440 or 540 attaches, A leg 755 connects the mount flange 750 to a lower joint 760 base that forms a channel 770. First and second clamp plates 780 and 785 are disposed to be respectively adjacent to the mount flange 750 and the leg 755, the latter within the channel 770. Screws 790 secure the plates 780 and 785 to their respective counterparts, and screws 795 attach the base 440 or 540 to the mount flange 750. The screws 790 enable the first compression plate 780 to be tightened against the platform 240 wedged against the channel 770.
The port instrument 220 has additional inputs. Fire 855, Ammo-Can-Select Toggle 860, Rate-of-Fire Toggle 865, Field-of-View Toggle 870 and Camera-Select Toggle 875 commands feed respectively from the P0.3, P0.4, P0.5, P0.6 and P0.7 to the trigger 460, and the push buttons 420: first 422, second 424, third 426 and fourth 428. The DAQ 830 at channels AI0 and AI1 receives Elevation 880 and Azimuth 885 command signals from the joystick 520. Each of these components in their respective controls 210, 220 include connection to electrical ground (GND). The joystick 520, palm switch 580 and trigger 560 connect to ground 890 for the starboard instrument 220. The trigger 460 and push buttons 420 connect to ground 895 for the port instrument 210.
Supplemental views are provided in the subsequent images.
The control instruments 210, 220 in various exemplary embodiments include a commercial off-the-shelf (COTS) DAQ 830 and any number of user-input devices (buttons, knobs, joysticks) mounted in two respective “stiff stick” control grip handles 430, 530, along with the monitor 250. The DAQ 830 connects to the monitor 250 via the USB interface 815, as well as supplied drivers. The buttons 420 and 525 receive their power from and transmit inputs to the DAQ 830. These signals can then be interpreted by the monitor 250 containing software to read the DAQ 830.
The information gathered from the DAQ 830 can then be used to control other devices. The control instruments 210, 220 each feature a respective pistol-grip handle 430, 530, a “button space” that corresponds to the workspace of the human thumb, as well as an inward slope and a backside palm switch 580, both of which are designed to reduce fatigue. These control instruments 210, 220 are designed to be produced, for example, by either machining or casting, and enable right-handed or left-handed bias pistol-grips 430, 530 to be produced from similar parts, including the grip stock 630.
The advantages of this system include ease of reconfiguration and modularity. Physically, a new operator input device can be inserted merely by cutting an additional hole in the face of the grip head 410, 510 and extending extra wires to the DAQ 830. The inward slope of pistol-grip handles 430, 530, as well as the positions of the buttons 420 and 525, the thumb joystick 520, the backside palm switch 580, also reduce operator fatigue and strain. The high level of mechanical division also allows for rapid reconfiguration of buttons 420 (or arrangement of “button space”) on the head 410.
There exist various conventional COTS user input instruments. Typically, these conventional instruments do not easily facilitate reconfiguration. Such designs that can be reconfigurable are usually limited to certain device types in specified conditions or environments. The various exemplary embodiments described herein obviate these limitations with modular ergonomic features.
While certain features of the embodiments of the invention have been illustrated as described herein, many modifications, substitutions, changes and equivalents will now occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the embodiments.
The invention described was made in the performance of official duties by one or more employees of the Department of the Navy, and thus, the invention herein may be manufactured, used or licensed by or for the Government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.