Braille Dot Delivery System

Abstract

The Braille Dot Delivery System is an enhancement design from the Publication No.: US-2012-0295232-A1, which implements the same concept for delivering Braille Dot characters via electronic pulses; the system comprises of the Low Frequency Pulse Output Device Pad [140] and the Computer/Signal Transmitter [200], where the wireless receiving unit receives information from the Computer/Signal Transmitter [200] generates electrical pulse(s) to replicate a Braille dot-like character. The Low Frequency Pulse Output Device Pad [140] contain electrodes in a 32 matrix cell; each cell consists of a set of electrodes, one for positive signal and another negative signal or ground; completing the circuit is the electrode gel pad, a medium between the electrode cell insert and human skin surface contact, there delivers an electronic pulse at low applied current. The Computer/Signal Transmitter [200] allows for creating Braille Dot characters by the key buttons and functions as a central processing unit to communicate, transmit, and receives information with other devices like smart phone, tablet, laptop, desktop, World Wide Web, and other communication devices.

Claims

1. A Braille Dot Delivery System is said to contain a Low Frequency Output Device Pad attached to a frame straps around the thenar region of the hand, along with a Computer/Signal Transmitter as a central processing unit.

2. In accordance with claim 1, wherein said, a Low Frequency Output Device Pad that adhere flushed to the thenar region of the hand, is said to deliver low electric current that replicate a Braille dot characters by method of placing a set of electrodes within a cell slot.

3. In accordance with claim 1, wherein said, the Low Frequency Pulse Output Device Pad is compose of a 32 electrode cell matrix, affixed on each cell an electrode gel pads; placed within the cell, there contain two electrodes; one positive (+), separated by an insulator to the other negative/ground (); with low electrical pulse, enough for the human skin surface to sense, allows for the electric current to passes through.

4. In accordance with claim 1, wherein said, the Low Frequency Pulse Output Device Pad delivers Braille word, sentences, etc. language by method of implementing an electric current sequencing and/or scroll-like techniques when features are programmed.

5. A Braille Dot Delivery System, wherein embodies a Computer/Signal Transmitter, designed to curve wraps around the forearm, comprises of input keys to position for ergonomic accessibility when generating Braille dot characters; in addition transmit, receives and interact other communication devices.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] Below is a brief description of the drawings, which also illustrates the components assemblies, applications, and views along with the reference number for the Braille Dot Delivery System:

[0015] FIG. 1 illustrates a three-dimensional assembly view of the Braille Dot Delivery System wireless receiving unit that delivers the electrical pulse to replicate Braille Dot character along with the essential support straps for the hand.

[0016] FIG. 1A illustrates a three-dimensional assembly view details the connection of the upper and lower body frame of the hand support strap with adjustable dorsum pad for adjustments to fit the dorsum area of the back of the hand.

[0017] FIG. 2 illustrates the entire assembly of the main computer pad slightly curved design contains ergonomic input keys, slot, and communication port.

[0018] FIG. 2A illustrates the entire assembly of the other end of the main computer, which comprises of the standard communication ports, slots, and power charging port.

[0019] FIG. 3 is a detailed illustration of the wireless receiving unit pad for delivering low frequency electric pulse, contains a set of positive and negative electrodes paired inside each of the 32 cell matrix insert hole, for delivering Braille Dot character.

[0020] FIG. 3a are illustration of a set of positive and negative paired electrodes arranged in a 32 cell matrix for placement in a cell matrix insert.

[0021] FIG. 3b are close up of the electrode gel pads for contacts between the device pad and human skin surface, which skin surface can detect electric pulse as Braille Dot character.

[0022] FIG. 4, is an application illustration of the wireless receiving unit pad placed at the hypothenar eminence area of the hand and support strap to the thenar eminence of the hand.

[0023] FIG. 5, is an application illustration of the slightly curved computer pad placed at the antebrachial of the arm.

[0024]

TABLE-US-00001 DRAWINGS - Reference Numerals 10 Position Electrode (A1) 12 Position Electrode (B1) 14 Position Electrode (A2) 16 Position Electrode (B2) 18 Position Electrode (A3) 20 Position Electrode (B3) 22 Negative Electrode () 24 Electrode Gel Pad 26 Electrode Gel Slot 120 Frontal Swing Frame 122 Upper Body Frame 124 Thenar Support Pad 126 Slider Button 128 Thenar Support Strap 130 Dorsum Cushion Pad 132 Adjustable Dorsum Knob 134 Lower Body Frame 136 Lock Pin 138 DC Power Supply Port 140 Low Frequency Pulse Output 142 Headphone Port Device Pad 144 Microphone Port 200 Computer/Signal Transmitter 201 Key Button (A1) 202 Key Button (A2) 203 Key Button (A3) 204 Key Button (B1) 205 Key Button (B2) 206 Key Button (B3) 207 Shift Button 208 Back Space Button 209 Enter Button 210 Micro USB Slot 212 Battery Pack Slot

DETAILED DESCRIPTION OF THE INVENTIONFIG. 1EMBODIMENT

[0025] A preferred embodiment in FIG. 1 derive a hand brace of the Braille dot delivery system, which components consist of the Frontal Swing Frame [120] attached to the Upper Body Frame [122] with an adjustable Slider Button [126], at the other end connects to a Lower Body Frame [134] with Lock Pins [136] allows for the Dorsum Cushion Pad [130] to center rest at the dorsum region of the back hand, along with an Adjustable Dorsum Knob [132] motions about normal to the dorsum region of the hand. The wireless receiving unit pad is the Low Frequency Pulse Output Device Pad [140], there attaches to one of the ends of the Lower Body Frame [134], adjustable and pivots implement through a Slider Button [126]. The Thenar Support Strap [128] with the Thenar Support Pad [124] ends are attached to the Upper Body Frame [122] and Frontal Swing Frame allows for quick fastening.

DETAILED DESCRIPTIONFIG. 1AEMBODIMENT

[0026] A preferred embodiment in FIG. 1A derives an assembly of the Upper Body Frame [122] and Lower Body Frame [134] where the Lock Pins [136] secure frame; the Dorsum Cushion Pad [130] place center normal to the body frame with rotating Adjustable Dorsum Knob [132].

DETAILED DESCRIPTIONFIGS. 2 AND 2AEMBODIMENT

[0027] An embodiment of the Computer/Signal Transmitter [200] is slightly curved, comprises of input buttons, places the Position Keys [201], [202], [203], [204], [205], [206], Shift Key [207], Back Space Key [208] at normal to the larger surface of the computer; at smaller surface, positioned the Enter Button key [209] with unit Battery Slot [212], and a standard Micro-USB Slot [210] at the smaller side, allowing for standard USB ports [146], Headphone Port [142], Microphone Port [144], and DC power supply port [138] as standard communication ports placed at opposite end.

DETAILED DESCRIPTIONFIG. 3EMBODIMENT

[0028] A preferred embodiment of the wireless receiving unit pad derives a Low Frequency Pulse Output Device Pad [140] contains a 32 matrix cell; within each cell slots are positive Position Electrode [10], [12], [14], [16], [18], [20] and Negative Electrode [22] separated by an insulator are the Negative Electrode [22]; normal to the surface of each cell slot of the Position Electrodes [10], [12], [14], [16], [18], [18] and Negative Electrode [22] are slots the Electrode Gel Slot [26].

DETAILED DESCRIPTIONFIG. 3A, AND 3BEMBODIMENT

[0029] An embodiment in FIG. 3a an 3B comprises of the paired electrodes arranged in a 32 cell matrix, where the Position Electrodes [10], [12], [14], [16], [18], [20] are placed towards the inner arrangement within the 32 cell matrix; where as, the Negative Electrodes [22] connected to ground positioned towards alongside the 32 cell matrix arrangement; with the Electrode Gel Pads [24] at nominal diameter and thickness to be placed within each of the 32 cell matrix inserts.

DETAILED DESCRIPTIONFIG. 4EMBODIMENT

[0030] An embodiment of the Braille Dot Delivery System in FIG. 4 exhibits an application method, where the wireless receiving unit pad, the Low Frequency Pulse Output Device Pad [140] rest flushed on the hypothenar region of the palm, with support of the Thenar Support Strap and Pad rest along the thenar region of the hand.

DETAILED DESCRIPTIONFIG. 5EMBODIMENT

[0031] An embodiment of the Braille Dot Delivery System in FIG. 5 exhibits an application method, where the Computer/Signal Transmitter [200] rest securely on the forearm of the arm demonstrates finger typing for inputting information and communication to the Low Frequency Pulse Output Device Pad [140].

OperationsFIGS. 3-3B, 4 and 5

[0032] The Braille Dot Delivery System comprised of the Low Frequency Pulse Output Device Pad [140] and the Computer/Signal Transmitter [200], was developed as a two separate unit for user ergonomically handling. The Low Frequency Pulse Output Device Pad [140] contains pair of electrodes positioned in a 32 matrix cell format, with each pair of positive and negative electrodes per for current passage, topped with an electrode Gel Pads [24] delivers just enough electric current to be felt by the human surface body. Calibration of the low level electric current delivery for sensing with human skin contact will varies from individuals to individuals.

[0033] When the Low Frequency Pulse Output Device Pad [140] is placed flushed at the hypothenar region of the palm, then secure strap with the body frame and dorsum pad, character development of a Braille Dot can deliver; observing the Low Frequency Pulse Output Device Pad [140], low level electric current or currents are required to pass through the positive Position Electrode [10], [12], [14], [16], [18], [20] and onto the Negative Electrode [22] as the Electrode Gel [24] adhering to the human skin surface provide a protruding dot effect.

[0034] The Low Frequency Pulse Output Device Pad [140] receives information wirelessly from the Computer/Signal Transmitter [200]. Depending on the number of Braille dot protrusion needed to develop Braille dot characters, each Position Electrodes may receive current signal simultaneously within the 32 matrix cells. To develop Braille Dot words, sentences, etc., program features within the Computer/Signal Transmitter [200] can be generated to sequencing electric current(s) or scroll-like signals features, then pass on to the Low Frequency Pulse Output Device Pad [140] wireless, there generates current to each matrix cell accordingly to deliver to human skin surface for Braille Dot characters.

[0035] As the main computation, the Computer/Signal Transmitter [200] receives two basic signals; one of the signals are from the ergonomics input Key Buttons [201], [202], [203], [204], [205, [206]; when pressed to developed a Braille Dot character words, signal is received for confirmation within the Computer/Signal Transmitter [200], then transmit via wireless communication to the Low Frequency Pulse Output Device Pad [140] to delivers Braille Dot character to the human skin surface for sensing. The second signal may be from other communication and peripheral devices such as smart phone, tablet, laptop, desktop, etc. and the World Wide Web. Additional features of the key buttons may be programmed for quick direct/access button. The Computer/Signal Transmitter [200] is design to fit onto the forearm region of the hand, is slightly curved with a strap to secure the device. There contains standard communication ports like that of a USB ports, Micro USB port, headphone, battery slot and DC power supply port.