ES2601193A1 - Application of a quaternary language for computer (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

The application of a quaternary computer language is a basic hardware system that each letter of a computer keyboard will multiply by four to signify the four proper numbers of a quaternary language. This basic system consists of a main cable (1), a transistor (2) and a resistor (3) that are joined to a metal plate (4), to which is also connected the cable (5) of the keyboard. This cable (5) has two thermistors (8, 17), and, bifurcates in two other parallel cables (6, 7). One of them (6) is directed towards a transistor (9), and, the other (7) is directed to a thermistor (11). Then, the ends of these three cables are connected to a second metal plate (13) which, on the other hand, is connected to the component of the computer that is responsible for translating the described hardware system into the software. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Application of a quaternary computer language.

Object of the invention 5

The main objective of the present invention is to be able to use a Quaternary Language in the hardware of a Computer, because this will allow to make programs much faster that, at least, will double the Process Speed of the Computers that use a Binary Language . The consequences of duplication of the 10 Speed are, among others, a higher Speed in the transmission of information via GPS, since the bit density that will be sent in each information will be reduced by half, which will directly affect the Radio, Television, Internet, and Telephony broadcasts.

 fifteen

Background of the invention

The main antecedent of the present invention is the elements that form the hardware of the Basic System presented, which later, as will be explained later, will be multiplied by four for each Letter of the Keyboard. These elements are known and common in Electronics, since they are Transistors, Thermistors and Resistors. Computers often use a Binary Language that is reduced to the fact that hardware, through a Conductor Cable, or, passes or does not pass the Current, which is meant as a One (1), or, a Zero (0). In this way, the Time in the transmission of the information in bits is doubled with respect to the Time in which a Quaternary Language 25 can send them. In this Quaternary Language, the fact of hardware to be considered is, not only if (1) passes, or, if the Current does not pass through one of the Cables, but also, if this Current exceeds a certain value (2), or, if it does not reach this same value (3), which allows us to add two more Numbers, Two and Three, to the Zeros and Ones of the Binary Language. 30

Description of the invention

The application of a quaternary language for computers is the hardware in which we will place the fundamental elements in which we apply the Quaternary Language. 35 We start with the Main Cable (1) through which the current of the circuit that has a certain Intensity and a certain Voltage circulates, and, the other two components that it has on both sides, - a Transistor (2) and a Resistance (3 ) -, which come through two other Cables, and, like the Main Cable (5), they are connected to a Metal Plate (4). To this Plate (4), it is also connected, on the other side, and, at the same connection point 40 as Cable (1), a second Main Cable (5) corresponding to a component, -one of the keys from the computer keyboard, for example-, which goes directly to the Second Metal Plate (13) to which it joins at the Connection Point (15).

To the Cable (5) two bifurcations are added in parallel (6, 7). One of the bifurcations 45 (6) leads to a Transistor (9) that, with a Cable (10), connects to the Metal Plate (13) at the Connection Point (14). The other fork (7) leads to a Thermistor of the type (PCT), whose Cable (12) is connected to the Connection Point (16) of the Board (13). The Cable (5) also has two Thermistors (8, 17) located in Series, one of type (NTC) and one of type (PTC), which will not let the Current pass when it has a Power greater than or less than 50 that of the threshold Power of the Main Current of the Circuit. He

Operation of this System is explained in detail in the following Description section of a preferred embodiment. Date of the invention: (11.08.15)

Description of the figures

 5

Figure 1: Plan view of the fundamental elements of the hardware system to which we apply the Quaternary Language. On the left we have three Cables that come from one of the Keyboard Keys that the Comment has sent to one of these three elements: the Main Cable (1), the Transistor (2), or, the Resistance (3) that are connected to the First Metal Plate (4). 10

The Cable (5), which has two Thermistors (8, 17), branches into two other Cables (6, 7). One of the Cables (6), leads to a Transistor (9), and, the Cable (7) leads to a Thermistor (11). The three Cables will then be connected to a second Metal Plate (13) which, on the other hand, will be connected to the Computer component that will translate the hardware of these electrical pulses, to the software of the programs you use .

Figure 1:

1) Main cable 20

2) Transistor

3) Resistance

 25

4) Metal cable connection plate (5)

5) Cable connected to a component

6) Bifurcated cable to Transistor 30

7) Forked cable to the Thermistor

8) Thermistor type (NTC)

 35

9) Transistor

10) Plate connection cable (13)

11) Thermistor type (PTC) 40

12) Plate connection cable (13)

13) Output cable connection plate

 Four. Five

14) Transistor cable connection point with number (2) in the Quaternary language

15) Cable connection point with the circuit comment with the number (1) in Quaternary language 50

16) Thermistor cable connection point with number (3) in the Quaternary language

Description of a preferred embodiment

 5

The application of a quaternary computer language is characterized by being a hardware system, in which, as seen in figure 1, on the left side we have three Cables that come from one of the Keyboard Keys, which has sent the Current to one of these three elements, the Main Cable (1), the Transistor (2), or, the Resistance (3). The Cable (5) that collects that Current can have the same value of 10 Circuit Current, -the one that arrives through the Cable (1) -, in which case, the Current will follow the Cable (8) and will connect to the Point Connection (15) of the Second Metal Plate (13). This number of Current of the Circuit will correspond the number (1) in the Quaternary Language. The Circuit Current, due to its specific value, may not pass through either the Transistor (9) or the Thermistor (11). Only the two Thermistors (8, 17) that it has in its Cable, which can only pass a specific Power such as that of the Circuit Current, and can not pass a Current, can pass through, for their specific value of 15 Power. Major, not a minor.

We have, therefore, two Quaternary Language Numbers. The zero (0), for when 20 does not pass any Current through the Cable (5), and, the one (1), for when the Circuit Current manages to reach the Connection Point (15) of the Second Plate (13 ). We will now locate the Number (2) of the Quaternary Language. In the event that the Current reaches the First Plate (4) from the Transistor (2), which can also be a Coil, where we will grow its Power, this Power will not be able to follow the 25 Cable path ( 5) towards the Second Plate (13), because it will be prevented by a Thermistor (8), or, the other (17), nor can it cross the third Thermistor (11) of the forked Cable (7) because its Power will be too high . And, therefore, this Current has no other choice but to go through the Transistor (9) since, only he, is qualified to assume such high Power. When this Current reaches the Plate (13), it will correspond to 30 Number (2), with which we already have three of the Numbers sought. We turn to Number (3) of the Quaternary Language.

In the event that the Current reaches the Plate (4) from the Cable where the Resistance (3) is located, its Power will be greatly reduced, and, when passing through the Cable (5), this Power will not be able of crossing the Transistor (9), nor the other two Thermistors (8, 17), so you will have no choice but to go through the Thermistor (11) and its Cable (12), which will allow you to reach the Point of Connection (16) of the Second Metal Plate (13), where the Number (3) of the Quaternary Language will correspond. Each Letter of the Keyboard, therefore, will be connected to Four Parallel Systems as described, which will be connected, all of them, one above the other, to the Second Metal Plate (13), to which they will also be connected, by the on the other hand, the Cables that will direct these received electrical pulses, towards the component that will have to translate to the Software the four Numbers that will have arrived to him, that is to say, the four simultaneous pulses of Current of each one of the Four Parallel Systems. Thus, as an example, the Letter that corresponds to Number (0123), will not have sent Current to the First System connected in the upper zone of the Plate (13), to which the Number (0) corresponds. Towards the Second Parallel System, the Letter will have sent a current pulse that will have passed through the two Thermistors (8, 17), to which corresponds the Number (1) in the second Lower Immediate System, connected to the Plate (13) . The same Letter, at the same time, towards the 50 Third Parallel System, which is connected below those before the

Plate (13) -, will have sent a pulse of current that will have crossed, only, the Transistor (9), to which the Number (2) will correspond. And, to the Fourth Parallel System, connected in the lower zone of the Plate (13), the current pulse will have reached that will only have passed through the Thermistor (11), to which the Number (3) will correspond. Now, the Software that is connected on the other side of the Board (13), to these Four 5 Parallel Systems, can understand that it is a specific Letter and not another, because, each of the Keyboard Keys, sends four simultaneous Current pulses that will correspond to these four different Numbers.

If in the Binary Legislation you get (256) combinations with only two Numbers 10 raised to the Power of eight, (28), in the Quaternary Language you get those same (256) combinations, with only four Numbers raised to the Power of four , (44), which means that the Process Speed, in this Computer that uses a Quaternary Language, will have doubled with respect to the Process Speed of a Computer that uses a Binary Language. fifteen

Claims (2)

1. Hardware for Quaternary Language, characterized by the Main Cable (1), and, the other two components that it has on both sides, - a Transistor (2) and a Resistance (3) -, which come by two other Cables, and , like the Main Cable (5), they are connected to a Metal Plate (4). To this Plate (4), it is also connected, on the other side, and, at the same connection point as the Cable (1), a second Main Cable (5) corresponding to a component, (one of the keys of the computer keyboard, for example), which goes directly to the Second Metal Plate (13) to which it joins the Connection Point (15). To the Cable (5) two bifurcations are added in parallel (6, 7). 10 One of the bifurcations (6) leads to a Transistor (9) which, with a Cable (10), connects to the Metal Plate (13) at the Connection Point (14). The other fork (7) leads to a Thermistor of the type (PCT), whose Cable (12) is connected to the Connection Point (16) of the Board (13). The Cable (5) also has two Thermistors (8, 17) located in Series, one of type (NTC) and one of type (PTC). fifteen 2. Hardware for Quaternary Language, according to claim one, characterized by the variant in which we replace the Transistor (2) with a coil of copper wire.