Abstract:
A diacritic chording system uses a single standard keyboard layout to generate diacritical characters used, for example, by Latin-based languages or languages based on a Roman character set, providing a universal keyboard The key combination required to select a diacritic is consistent, independent of the language the user is typing. The diacritic chording system uses chording to obtain characters modified by diacritics, i.e., diacritical characters. The key combinations in the diacritic chord are chosen in such a way to aid memorization by positional association of the keys or by logic association of the keys within the diacritic chord. The use of a combination of positional association and logical association eliminates conflicts in mapping diacritics for different languages. The diacritic chording system also provides a screen overlay as a mnemonic to illustrate which diacritic chords provide the desired diacritical character.

Description:
FIELD OF THE INVENTION 
     The present invention generally relates to a method for generating specialty characters from a generic keyboard, and in particular to generating diacritics used by languages, such as European languages. More specifically, the present invention provides a method for generating diacritics required for many different languages from a universal keyboard. 
     BACKGROUND OF THE INVENTION 
     Current keyboards are primarily used for data entry and are specifically designed for specific languages. As an example, U.S. English keyboards lack numerous accents, dieresis, cedillas and other diacritical marks (collectively referred to herein as diacritics) that are necessary to correctly type non-English languages. A character utilizing a diacritic is referenced herein as a diacritical character. In the increasingly global marketplace, a native of a country fluent in several languages may be working in the U.S. This person could find it difficult to communicate fluently in a European language because the U.S. keyboard has a limited number of diacritics available to the user. 
     A conventional approach to providing diacritics essential to a language is to utilize “national keyboards” that generate language specific accented characters. Typically, commonly used diacritical characters are assigned a unique key on the keyboard. Thus, for example, it is common to find the diacritical character “ñ” on a Spanish keyboard but not on a French keyboard since the “tilde” is not used in the French language. Similarly, the diacritical characters “à”, “é” and “ù” are found on most French keyboards but not on Spanish keyboards while the diacritical characters “ä”, “ö” and “ü” are found on German keyboards. However, each keyboard is designed primarily for one language. Persons who write in more than one language are required to either switch keyboards and use a different keyboard driver application tailored to the desired language, or improvise to generate the desired diacritic. 
     One problem arising from the use of national keyboards is that even though two keyboards may contain the same characters, their positions may be quite different. Thus, the position of the acute and grave accents on a keyboard designed for France is different from that of a keyboard design for Italy. Switching keyboards requires the user to remember different keyboard layouts, a complication that potentially slows keyboarding by the user. Further, switching keyboards requires additional keyboard driver applications as the placement of characters on the keyboard is different. 
     Conventional word processing applications make use of so-called “dead keys” to obviate the need for backspacing while entering accented characters that are not assigned a unique key. It will be appreciated that the keyboard would be much too large if every possible accented character were assigned a unique key. With a dead key, the operator initially selects the dead key appropriate to the required diacritic and then selects the appropriate character key to produce a diacritical character. This dead key enters the accent but does not advance the display. Reference is made to U.S. Pat. No. 4,204,089. 
     Only a few characters can be assigned to the dead keys, while over twenty-five different diacritical modifiers are required for European languages. In addition, some European characters use diacritics that are not modifications of existing characters but unique characters on their own. Consequently, these diacritical characters do not translate well to a “dead key” approach. 
     Another conventional approach to generating diacritics is to use a compose key. A key on a keyboard is designated as a “compose” key. Pressing the compose key and then a sequence of keys causes a keyboard driver application to interpret the sequence of two or three characters as a composition: i.e., &lt;compose&gt;+{grave over ( )}+a=à. However, the user is required to remember many different combinations to produce the desired diacritical character, slowing the keyboard entry speed of the user. 
     Yet another conventional approach utilizes a repetition method. A user repeatedly presses a key to cycle through possible diacritics for the desired diacritical character. For example, one press of the letter “a” yields “a”. A second press of the letter “a” yields “à”. A third press of the letter “a” yields “á”. A fourth press of the letter “a” yields “ä”, etc. (Reference is made to U.S. Pat. No. 6,340,937.) However, the user is required to either remember where in the cycle the desired character is produced or focus on the keyboard and screen when cycling through the possible characters. This approach also slows keyboard entry speed of the user. 
     What is therefore needed is a system, a computer product, and an associated method that allow the use of a single keyboard (or an input keypad) to produce diacritics for different languages that use, for example, a Latin-based character set or a Roman character set. Further, a method is needed that allows a user of a U.S. keyboard to generate properly shaped diacritics in other languages in a user-friendly format. The need for such system and method has heretofore remained unsatisfied. 
     SUMMARY OF THE INVENTION 
     The present invention satisfies this need, and presents a system, a computer program product, and an associated method (collectively referred to herein as “the system” or “the present system”) for using a standard keyboard such as a U.S. keyboard to conveniently generate diacritical characters used by Latin-based languages or languages based on a Roman character set. The present system allows users to type in many different languages from one keyboard layout, providing a universal keyboard for all languages using a Latin-based character set or a Roman character set. The key combination required to select a diacritic is consistent, independent of the language the user is typing. 
     The present system uses, for example, the normal U.S. QWERTY keyboard. Many conventional computer keyboards can detect three or four keys pressed at the same time. More than one key pressed at one time is referenced as a diacritic chord; the operation of pressing more than one key at a time is referenced as chording. The present system uses chording to obtain Latin-based characters or Roman characters modified by diacritics, i.e., diacritical characters. 
     The key combinations in the diacritic chord are chosen for the present system in such a way to aid memorization by positional association of the keys or by logic association of the keys within the diacritic chord. Use of a combination of positional association and logical association by the present system eliminates conflicts in mapping diacritics for different languages. 
     Positional association uses the relative positions of the keys within a diacritic chord to aid memorization or recall of the diacritic chord corresponding to a diacritical character. With positional combinations, locations of keys within the diacritic chord are similar to the shape of the diacritical character. For example, a user selects a grave accent ({grave over ( )}) by pressing a vowel key in conjunction with the key on the upper left of the vowel key. The grave accent leans to the left and the key on the upper left of the vowel key produces the desired diacritic; this combination is easy to remember from relative position of the keys. The user selects an acute accent (´) by pressing a vowel key in conjunction with the key on the upper right of the vowel key. The acute accent leans to the right and the key on the upper right of the vowel key produces the desired diacritic; again, this combination is easy to remember from the relative position of the keys. 
     Rather than memorizing an unrelated key combination, a user can remember the required diacritic chord by simply looking at the keyboard layout. By building on existing keyboarding skills, the user can easily extend keyboarding capability to encompass a large number of diacritic characters. 
     The positional combination is associated with the desired letter. A user does not have to remember one key where the desired diacritic is located. Rather, the user remembers the diacritic relative to the modified letter. A user can select an umlaut by pressing a diacritic chord comprising the desired letter and both keys above the letter. Consequently, the user memorizes one template that can be applied to, for example, all vowels. 
     Logical association uses association of shape or sound to select the desired diacritic. For example, an umlaut used in German appears like a double quote (″). The present system produces a character modified by an umlaut when the user presses the letter and the double quote as a diacritic chord. For example, pressing the letter “a” and the double quote (″) together yields the diacritical character, ä. Association of sound is used to produce the thorn character that sounds like “th”; the user presses a diacritic chord comprising the letter “t” and the letter “h”. 
     The present system uses logical association to generate symbols. In the example illustrated below, pressing the dollar sign ($) with another key produces a monetary notation: 
     pressing $+&amp;=            (euro); ($+e conflicts with é).
     pressing $+y=¥ (yen); 
     pressing $+p=£ (pound, lira); and 
     pressing $+c=¢ (cent), etc. 
     The “+” symbol indicates that the keys are pressed concurrently, in a diacritic chord. 
     The present system provides alternate diacritic chords for producing a diacritic character, allowing a user to select a diacritic chord that is most easy to remember. For example, a user selects an umlaut by pressing a diacritic chord comprising the desired letter and the double quote (″). Alternatively, the user selects an umlaut by pressing a diacritic chord comprising the desired letter and the two keys directly above the letter. For example: 
     pressing a+″=ä or pressing q+w+a=ä; 
     pressing e+″=ë or pressing 3+4+e=ë; 
     pressing i+″=ï or pressing 8+9+i=ï; 
     pressing o+″=ö or pressing 9+0+o=ö; and 
     pressing u+″=ü or pressing 7+8+u=ü. 
     Providing alternate diacritic chords allows the user to use as few keys as possible in a diacritic chord. For example, q+w+a=ä requires three keys. However, selecting a Ä requires four keys: shift+q+w+a=ä. The alternative diacritic chord for Ä requires only three keys: shift+a+″=ä. 
     The present system provides a help screen overlay as a mnemonic to illustrate which diacritic chords provide the desired diacritical character. For example, a user presses a function key and the letter “a” to view all possible diacritic chord combinations that use the letter “a”. In this manner, a user can quickly learn the diacritic chord combinations that produce diacritical characters for different languages. 
     In one embodiment, a mapping for producing desired diacritical characters is printed on a keyboard to provide a visual mnemonic for the user. In another embodiment, an input such as, for example, a function key restricts available diacritics to a selected language. In yet another embodiment, an input such as, for example, a function key is selected to enable or disable the help screen overlay. 
     In a further embodiment, the present system emits key-down events while comparing characters represented by the key-down events with a table of diacritic chords. Characters that are found to be part of a diacritic chord are stored in a queue in a buffer. If a diacritic chord is formed, the present system emits a backspace with the diacritic character. The backspace removes the previously emitted character from the screen, replacing it with the diacritic character. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The various features of the present invention and the manner of attaining them will be described in greater detail with reference to the following description, claims, and drawings, wherein reference numerals are reused, where appropriate, to indicate a correspondence between the referenced items, and wherein: 
         FIG. 1  is a schematic illustration of an exemplary operating environment in which a diacritic chording system of the present invention can be used; 
         FIG. 2  is a timeline illustrating a performance of the diacritic chording system of  FIG. 1 ; 
         FIG. 3  is a timeline illustrating a performance of an embodiment of the diacritic chording system of  FIG. 1 ; 
         FIG. 4  is comprised of  FIGS. 4A ,  4 B,  4 C, and  4 D and represents an exemplary table of diacritic chords used by the diacritic chording system of  FIG. 1  to produce diacritical characters; 
         FIG. 5  is a schematic illustration of an exemplary keyboard illustrating a visual mnemonic indicating keys that can be used by the diacritic chording system of  FIG. 1  to generate diacritical characters; and 
         FIG. 6  comprises  FIGS. 6A and 6B  and represents a process flow chart illustrating a method of operation of the diacritic chording system of  FIG. 1 . 
     
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     The following definitions and explanations provide background information pertaining to the technical field of the present invention, and are intended to facilitate the understanding of the present invention without limiting its scope: 
     Diacritic: A mark, such as the cedilla of facade or the acute accent of résumé, added to a letter to indicate a special phonetic value or distinguish words that are otherwise graphically identical. 
     Diacritical character: a character that comprises a diacritic or is otherwise unique to a language or set of languages such as, for example, the thorn character. 
     Diacritic chord: a set of keys pressed concurrently that are used to identify a diacritical character. 
       FIG. 1  portrays an exemplary overall environment in which a system, a computer program product, and an associated method (“the system  10 ”) for producing language specific diacritics for many languages from a standard keyboard layout according to the present invention may be used. The diacritic chording system (system  10 ) includes a software programming code or computer program product that is typically embedded within, or installed on a computer system  15 . Alternatively, system  10  can be saved on a suitable storage medium such as a diskette, a CD, a hard drive, or like devices. 
     System  10  may be installed in a keyboard driver  20  of the computer system  15 . In one embodiment, system  10  may be installed in the operating system  25  of the computer system  15 . In a further embodiment, system  10  may be installed in a keyboard  30 . In yet another embodiment, system  10  may be installed in any one or more of the operating system  25 , the keyboard driver  20 , or the keyboard  30 . Characters generated by keyboard  30  are transmitted for display on a screen  35  either by the operating system  25  or an application  40  running on the computer system  15 . Actions described herein as performed by the operating system  25  may be performed either by application  40  or by the operating system  25 . 
     System  10  comprises a mechanism to detect simultaneous key-down events. System  10  intercepts key events from keyboard  30 . Key-down events interpreted by system  10  as occurring concurrently are stored in a buffer. Concurrent key-down events are interpreted by system  10  as a diacritic chord. System  10  interprets as a diacritic chord all key-down events that occur within a predetermined time threshold. The predetermined time threshold can be adjusted for a specific keyboard. Typically, the predetermined time threshold is approximately 100 msec or less. 
       FIG. 2  illustrates an exemplary timeline  200  of key-down and key-up events in generating a letter “a” with a grave accent. Timeline  200  comprises a timeline  205  for keyboard  30 , a timeline  210  for system  10 , a timeline  215  for operating system  25 , and an output timeline  220  for screen  35 . The operating system  25  represents the operating system  25  and any applications that “draw” characters on screen  35 . At t 1    225 , a user presses an “a” key. A key event representing the letter “a” is transmitted to system  10 . System  10  stores the key event in a queue in a buffer at t 2    230 . 
     At t 3    235 , the user presses the “q” key while still holding down the “a” key. A key event representing the letter “q” is transmitted to system  10 . At t 4    240 , system  10  compares the two key events stored in the buffer to a table of diacritic chords representing diacritical characters, selects the appropriate symbol or character combination, and transmits a diacritical character “à” to the operating system  25 . The operating system  25  transmits the diacritical character “à” to screen  35  at t 5    245 . Screen  35  displays the diacritical character “à” at t 5    250 . The key-down events at t 1    225  and t 3    235  are not necessarily simultaneous. Rather, the key-down events at t 1    225  and t 3    235  are required by system  10  to occur within the predetermined time threshold, represented in  FIG. 2  as a threshold  255 . 
     If system  10  receives a key-up event after the key-down event at t 1    225  and before the key-down event at t 3    235 , system  10  transmits a key event representing the letter “a” to the operating system  25 . If the key-down event at t 3    235  occurs after the threshold  255  has expired, system  10  sends a key event representing the letter “a” to the operating system  25 . In this manner, system  10  distinguishes between key events that construct a diacritic chord for forming a diacritical character and key events representing individual characters. 
     The method of system  10  as represented by timeline  200  waits for a key-up event, the presence of key events in the buffer that represent a diacritic chord, or the expiration of the threshold  255  to transmit a character to screen  35 .  FIG. 3  illustrates a timeline  300  for one embodiment in which key events or characters are transmitted directly to screen  35 . When system  10  detects a diacritic chord for forming a diacritical character, system  10  transmits a backspace followed by the diacritical character. The backspace removes the previously transmitted character, replacing the previously transmitted character or characters with the diacritical character. 
     Timeline  300  comprises a timeline  305  for keyboard  30 , a timeline  310  for system  10 , a timeline  315  for operating system  25 , and an output timeline  320  for screen  35 . At t 1    325 , a user presses an “a” key. A key event representing the letter “a” is transmitted to system  10 . System  10  stores the key event in a queue in a buffer at t 2    330  and transmits the key event to the operating system  25 . At t 3    335 , the operating system  25  receives the key event. The operating system  25  transmits the character representing the key event to screen  35  at t 4    340 . 
     At t 5    345 , the user presses the “q” key. A key event representing the letter “q” is transmitted to system  10 . At t 6    350 , system  10  stores the key event in the buffer and compares the key events stored in the buffer to a table of diacritic chords representing diacritical characters. If the key events stored in the buffer correspond to a diacritical character, system  10  selects the appropriate symbol or character combination; in this example, system  10  transmits a backspace and a diacritical character “à” to the operating system  25 . The operating system  25  transmits the backspace and the diacritical character “à” to screen  35  at t 7    355 . The previously transmitted character is removed from screen  35  and the diacritical character “à” is displayed at t 8    360 . The key-down events at t 1    325  and t 5    345  are not necessarily simultaneous. Rather, the key-down events at t 1    325  and t 5    345  are required by system  10  to occur within the predetermined time threshold, represented in  FIG. 3  as a threshold  365 . 
     This embodiment allows transmission of a character directly to a screen  35 , reducing delays between the key-down event and appearance of the character on screen  35 . Otherwise, a character does not appear on screen  35  until after threshold  365  has expired so that system  10  can determine if the key-down event is part of a diacritic chord representing a diacritic character. As most of the letters entered by a user are not diacritic characters, this embodiment provides a means for more quickly transmitting characters to screen  35 . 
     As before, if system  10  receives a key-up event after the key-down event at t 1    325  and before the key-down event at t 5    345 , system  10  transmits a key event representing the letter “a” to the operating system  25 . If the key-down event at t 5    345  occurs after the threshold  365 , system  10  sends a key event representing the letter “a” to the operating system  25 . In this manner, system  10  distinguishes between key events that construct a diacritic chord for forming a diacritical character and key events representing individual characters. 
       FIG. 4  ( FIGS. 4A ,  4 B,  4 C,  4 D) illustrates a table  400  of exemplary diacritic chords or key combinations that system  10  uses to form diacritical characters. Most of the diacritical characters are formed using two keystrokes. A small proportion of diacritical characters are formed using three keystrokes. Upper case diacritical characters are formed by adding the “shift” key to the diacritic chord listed in  FIG. 4 . System  10  consults the table  400  of diacritic chords illustrated by  FIG. 4  when a diacritic chord is detected in the buffer. If a match is found, system  10  emits the resulting diacritical character. Otherwise, system  10  emits each character in the buffer individually. 
       FIG. 5  illustrates an exemplary keyboard  500  that comprises notations of the diacritical characters that may be formed by chording. For example, the key  505  for the number 6 is used in a diacritic chord to add a diacritic “^” to letters. A user can easily see by looking at the keyboard  500  that pressing a key  510  for the letter “a” and the key  505  for the number 6 in a diacritic chord generates a diacritical character “â”. The letter “u” with the diacritic ″ (symbol  515 ) is placed between a key  520  for the number 8 and a key  525  for the number 9 to indicate that symbol  515  is formed when a user concurrently presses a key  530  for the letter “u”, the key  520  for the number 8, and the key  525  for the number 9. 
       FIG. 6  ( FIGS. 6A ,  6 B) illustrates a method  600  of operation of system  10  for recognizing a diacritic chord and selecting a diacritical character corresponding to the diacritic chord. System  10  monitors keyboard  30  for key events at step  605 . When a key event occurs, system  10  determines whether the key event is a key-down event at decision step  610 . If the key event is a key-down event, system  10  determines at decision step  615  whether the character represented by the key-down event is part of a diacritic chord. If the character represented by the key-down event is not part of a diacritic chord, system  10  emits the key-down event at step  620 . At step  625 , system  10  continues with normal key processing and returns to step  605 . 
     If at decision step  615  the character represented by the key event is part of a diacritic chord, system  10  stores the key in a queue in a buffer at step  630  and starts a timeout timer for that key. At decision step  635 , system  10  determines whether keys accumulated in the queue match a diacritic chord in the table  400  of diacritic chords. If a match is found, system  10  empties the queue in the buffer, emits a key-down event and key-up event corresponding to the diacritic character in the table  400  of diacritic chords (step  640 ). System  10  proceeds to step  625  and processing continues as before. If no match is found at decision step  635 , system  10  proceeds to step  625  and processing continues as before. 
     If a key-down event is not detected at decision step  610 , system  10  determines whether the key event is a key-up event at decision step  645 . If yes, system  10  determines whether the key represented by the key-up event is currently stored in the buffer at decision step  650 . If the key represented by the key-up event is stored in the buffer, system  10  emits the key-down and key-up events for that key at step  655 . At step  660 , system  10  removes the key from the queue in the buffer and stops the timeout timer for that key. System  10  proceeds to step  625 , and processing continues as before. 
     If, at decision step  650 , system  10  finds that the key represented by the key-up event is not stored in the queue in the buffer, system  10  emits a key-up event at step  665 . System  10  proceeds to step  660  and processing continues as before. 
     If, at decision step  645 , system  10  determines that the key event is not a key-up event, system  10  determines whether the timer timeout has occurred at decision step  670 . If the timer timeout has occurred, system  10  emits a key-down event for the key currently stored in the queue in the buffer and stops the timeout timer for that key at step  675 . System  10  proceeds to step  660  and processing continues as before. 
     The character detection and transformation process of system  10  is implemented as procedures that run in different threads. A pseudocode for the character detection and transformation process is as follows: 
     Procedure Transform Characters 
     Variables: 
     
       
         
               
             
           
               
                   
               
             
             
               
                 THRESHOLD : INTEGER 
               
               
                 EMITTED : CHAR 
               
               
                 RESULT : CHAR 
               
               
                 BUFFER : LIST{CHAR} 
               
               
                 CONVERTED : LIST{CHAR} 
               
               
                 EVENT : KEY_EVENT 
               
               
                 MATCH : KEY_EVENT 
               
               
                 KEY_EVENT { 
               
               
                 TYPE : {KEY-DOWN, KEY-UP} 
               
               
                 TIMESTAMP : INTEGER 
               
               
                 CHAR : CHAR 
               
               
                 } 
               
               
                 do 
               
               
                 EVENT := readKeyboard( ); 
               
               
                 if EVENT.TYPE = KEY-DOWN then 
               
               
                  BUFFER.add(EVENT); 
               
               
                  // If the buffer contains two or more KEY-DOWN events a search is 
               
               
                 performed in the transformation table. If a match is 
               
               
                  // found the events are removed from the buffer and a KEY-DOWN 
               
               
                 event corresponding to the transformed character is send to 
               
               
                  // the normal key processing in their place. Another copy of the 
               
               
                 transformed character is put into the EMITTED variable. A copy 
               
               
                  // of the matching characters is put into the CONVERTED buffer. 
               
               
                  if BUFFER.size &gt; 1 then 
               
               
                   RESULT := transform(BUFFER) 
               
               
                   if RESULT != nil then 
               
               
                    EMITTED := RESULT 
               
               
                    CONVERTED := BUFFER 
               
               
                    BUFFER := nil 
               
               
                    sendToNormalProcessing(EMITTED) 
               
               
                   end 
               
               
                  end 
               
               
                 elseif EVENT.TYPE = KEY-UP then 
               
               
                  // If a KEY-UP is received and the corresponding KEY-DOWN event 
               
               
                 is still in the buffer, the KEY-DOWN event is 
               
               
                  // removed from the buffer and a KEY-DOWN and KEY-UP event 
               
               
                 are sent to normal event processing. 
               
               
                  MATCH := BUFFER.searchSameCharacterEvent(EVENT) 
               
               
                  if MATCH != nil then 
               
               
                   BUFFER.remove(MATCH) 
               
               
                   sendToNormalProcessing(MATCH) 
               
               
                   sendToNormalProcessing(EVENT) 
               
               
                  else 
               
               
                   MATCH := CONVERTED.searchSameCharacterEvent(EVENT) 
               
               
                   if MATCH != nil then 
               
               
                    // Otherwise, if the corresponding KEY-DOWN event 
               
               
                    // is in the CONVERTED buffer the KEY-DOWN 
               
               
                    // event is removed from CONVERTED. If this empties 
               
               
                    // CONVERTED a KEY-UP event corresponding 
               
               
                    // to the EMITTED character is sent to 
               
               
                    // normal key processing and EMITTED is cleared. 
               
               
                    CONVERTED.remove(MATCH) 
               
               
                    if CONVERTED.isEmpty( ) then 
               
               
                     EMITTED.TYPE := KEY-UP 
               
               
                     sendToNormalProcessing(EMITTED) 
               
               
                     EMITTED := nil 
               
               
                    end 
               
               
                   end 
               
               
                  end 
               
               
                 end 
               
               
                 end 
               
               
                   
               
             
          
         
       
     
     Another thread of the character detection and transformation process expires old key events: 
     
       
         
               
             
           
               
                   
               
             
             
               
                 procedure expireEvents 
               
               
                 variables 
               
               
                 THRESHOLD : INTEGER 
               
               
                 do 
               
               
                 THRESHOLD := 80 // milliseconds 
               
               
                 // If any timestamp of an event in the buffer is older than THRESHOLD 
               
               
                 milliseconds, 
               
               
                 // the event is removed from the buffer and sent to the normal key event 
               
               
                 processing. 
               
               
                 foreach CHARACTER in BUFFER 
               
               
                  if NOW - CHARACTER.TIMESTAMP &gt; THRESHOLD then 
               
               
                   BUFFER.remove(CHARACTER) 
               
               
                   sendToNormalProcessing(CHARACTER) 
               
               
                  end 
               
               
                 end 
               
               
                 end 
               
               
                   
               
             
          
         
       
     
     It is to be understood that the specific embodiments of the invention that have been described are merely illustrative of certain applications of the principle of the present invention. Numerous modifications may be made to the system and method for producing language specific diacritics for many languages from a standard keyboard layout described herein without departing from the spirit and scope of the present invention. Moreover, while the present invention is described for illustration purpose only in relation to diacritic symbols for Latin-based languages or languages using a Roman character set, it should be clear that the invention is applicable as well to, for example, any character set in which diacritic chords can be used to form additional characters.