DE19925675A1 - Pen computer - Google Patents

Abstract

The computer has an elongated pen body (10) with a writing end with a rotatable ball bearing (15) forming a ball point pen tip (16). First and second encoding groups (2,2') on the writing end of the pen body encode the movement of the ball bearing along X- and Y- directions to produce corresp. signals. A character recognition arrangement identifies the written characters from the X- and Y-signals.

Description

The present invention relates to a handheld computer or by hand held computer ("handheld"), especially on a pen computer that as a computer, directory manager and as an electronic dictionary can be used.

Address books and organizers are currently available to someone enable contact information from customers and chance acquaintances to write it down. However, if data is not in a clean and orderly manner have been written, you can search for the desired contact information by using traditional address books and organizers carry out.

Most electronic dictionaries and digital personal assistants (Personal Digital Assistants, PDA) currently include many added functions such as B. arithmetic functions, schedule Organizational functions and telephone directory administration functions, which increases their usefulness. However, these are electronic devices still relatively bulky and heavy, resulting in some inconvenience when wearing it.

Therefore, the main object of the present invention is to provide a pen To provide computers that act as computers, telephone directory administrators and as electronic dictionary can be used and the the aforementioned  Avoids disadvantages that are common with conventional electronic words books and digital personal assistants.

According to the present invention, a pen computer comprises: an elongated one Pen body, first and second coding groups and character recognition means. The Pen hull has a writing end, which with a rotatable Kugella is provided, which serves as a ballpoint pen tip. The pen trunk is designed so that it can be held in one hand to form characters on a writing surface over the ball bearing. The first coding group, the is located on the writing end of the pen barrel, encoding movement of the Ball bearing along an X direction and generates X axis drive signals correspondingly coded movement of the ball bearing along the X axis. The second coding group, arranged on the writing end of the pen barrel encodes movement of the ball bearing along a Y direction and generates Y-axis driver signals according to coded movement of the ball bearing along the Y axis. The character recognition means are in the pen body arranges and electrically connected to the first and second coding groups from there to receive the X-axis and Y-axis driver signals. The time Chemical detection means identify the ball bearing on the writing characters formed from the X-axis and Y-axis driver signals and generate computer codes that assign the characters identified thereby are not.

Preferably, the pen computer furthermore has computing means which in the Pen body are arranged and assigned to the character recognition means. In the event that the characters formed on the writing surface have an arithmetic tical expression, the computing means can be operated to the To process computer codes that identi. By the character recognition means are assigned to a result of the arithmetic expression to calculate.  

More preferably, the pen computer also has: a dictionary Database which is arranged in the pen body for storing information with regard to the words of a language and dictionary search means which in the Pen body are arranged and the character recognition means and the words book database are assigned. The dictionary search means can be operated to process the computer codes recognized by the characters Means identified characters are assigned to a word accordingly to determine the computer codes and to obtain the information according to the thereby retrieving a specific word from the database.

More preferably, the pen computer also has a directory Storage unit, which is arranged in the pen barrel, for storing a telephoto phone directory database in it and phone directory management means in the pen body are arranged and the character recognition means and Ver Drawing storage unit are assigned. In the event that the on the writing surface che formed characters a name and a contact number, the name assigned, the telephone directory management means in operate in a directory build mode to ver the computer codes work that the characters identified by the character recognition means are assigned to the name and contact number corresponding to the computer codes and to determine the name and the con store the cycle number in the directory storage unit.

Other features and advantages of the present invention are set forth in the fol ing detailed description with reference to the accompanying drawings are clear in which:  

Fig. 1 is a fragmentary schematic view showing a writing tip of the first preferred embodiment of a pen-based computer according to the present invention,

. 2 is a schematic view of Fig, before the first is a Kodiergruppe the ferred embodiment,

Fig. 3 is a schematic view illustrating the positional relationship ünter the Kodiergruppen and a ball bearing of the first preferred execution form,

Fig. 4 is a schematic view showing a rotatable member and a Sen soreinheit Kodiergruppe of the first preferred embodiment,

Figure 5 illustrates. The relationship between drive signals of the Kodiergruppen and the direction of movement of the ball bearing according to the first embodiment be vorzugten,

Fig. 6 is a time chart showing the drive signals of the first preferred embodiment, when movement of the ball bearing occurs only in a + y-direction,

Fig. 7 is a timing chart showing the drive signals of the Kodiergruppen the first preferred embodiment, if movement of the ball bearing in the -Y direction and a + X direction occurs in both a,

Fig. 8 is a time chart showing the drive signals of the Kodiergruppen the first preferred embodiment, if movement of the ball bearing direction X occurs only in a +,

9 is a fragmentary schematic sectional view of Fig. Fuselage of a pin of the first preferred embodiment,

Fig. 10 is a schematic circuit block diagram of a control unit of the first preferred embodiment,

FIG. 10A is a functional block diagram of a memory device of the control unit of Fig. 10,

FIG. 10B is a functional block diagram of a processor of the controller of Fig. 10,

Fig. 11 is a flow chart illustrating the operation of the first preferred exporting approximate shape,

12 is Fig. Is a flow chart illustrating the operation before the first of the processor of ferred embodiment in a calculation mode,

Fig. 13 is a schematic view which form a rotatable member and a Sen soreinheit a Kodiergruppe the second preferred execution of a pen-computer according to the present invention provides,

Fig. 14 is a schematic view which form a rotatable member and a Sen soreinheit a Kodiergruppe the third preferred execution of a pen-based computer according to the present invention represents.

Referring to Fig. 1, the first preferred embodiment of a pen computer 1 in accordance with the present invention is shown to have an elongated pen body 10 having a stylus formed with an axial opening 11 and a pair of orthogonal radial chambers which mate with that Opening 11 are connected via recesses 12 , 13 .

A rotatable ball bearing 15 extends from the pen barrel 10 outwards at the axial opening 11 to act as a ballpoint pen tip 16 . An ink supply unit 14 in the form of an ink core is arranged in the pen body 10 and supplies the ball bearing 15 with ink. In the preferred embodiment, the ball bearing 15 is rotatably supported at one end of the ink supply unit 14 . First and second coding groups 2 , 2 'are each arranged in the radial chambers at the writing end of the pin body 10 . The first coding group 2 encodes movement of the ball bearing 15 along an X axis and generates X drive signals corresponding to encoded movement of the ball bearing 15 along the X direction. The second coding group 2 ′ codes movement of the ball bearing 15 along a Y direction and generates Y drive signals in accordance with coded movement of the ball bearing 15 along the Y direction. With reference to FIGS. 1 to 4, each of the first and second coding groups 2 , 2 ′ has a frame part 22 , which is fixedly arranged in the respective radial chamber at the writing end of the pen body 10 . A rotatable shaft 220 is rotatably arranged on the frame part 22 . A contact part 20 , 21 in the form of a ball is fixedly arranged on the rotatable shaft 220 and extends into the pin body 10 via the recess 12 , 13 into it for contacting the ball bearing 15 . such that movement of the ball bearing 15 in a certain direction can cause rotation of the rotatable shaft 220 . The contact parts 20 , 21 touch the ball bearing 15 at vertical positions, as best shown in FIG. 3. A rotatable member 23 is fixed on the rotatable shaft 220 for rotation therewith. A sensor unit 24 is fixed on the frame holder 22 for generating the drive signals in response to detected movement of the rotatable part 23 .

Thus, when the pen barrel is held in one hand to form characters on a writing surface by means of the ball bearing 15 , the contact parts 20 , 21 rotate according to the direction of movement of the ball bearing 15 to rotate the respective rotatable shaft 220 and the associated rotatable part 23 cause. The X-axis and Y-axis drive signals are generated according to the following and each by the sensor units 24 of the first and second coding groups 2 , 2 'in response to detected movement of the corresponding rotatable part 23 .

In the first preferred embodiment, the rotatable member 23 is formed as a conductive member which has a central mounting portion 232 fixedly disposed on the rotatable shaft 220 and a number of equally spaced contact arms 230 which extend radially and outwardly from the central mounting section 232 extend. The rotatable member 23 is electrically connected to a most current source, such as. B. the ground connection of an energy supply unit. The central processing unit 24 has an insulator substrate 241 arranged on the frame part 22 in the vicinity of the rotatable part 23 and front and rear circuit boards 240 , 242 , which are arranged on front and rear sides of the insulator substrate 241 , respectively. The front and rear printed circuit boards 240 , 242 are electrically connected to a second power source, such as. B. the positive (or Vcc) connection of a power supply unit. When the contact parts 20 , 21 rotate in a corresponding first direction due to movement of the ball bearing 1 S, the contact arms 230 successively touch the front circuit board 240 to result in + X-axis and + Y-axis drive signals. Accordingly, when the contact members 20 , 21 rotate in a corresponding opposite second direction due to the movement of the ball bearing 15 , the contact arms 230 touch the rear circuit board 242 successively to drive in -X-axis and -Y-axis signals result. The relationship between driver signals from the first and second coding groups 2 , 2 'and the direction of movement of the ball bearing 15 is shown in FIG. 5. In the following three sampling conditions are mentioned in order to clarify the operation of the coding groups 2 , 2 ':

• 1. In the (+ Y <X = 0) status of FIG. 5, movement of the ball bearing 15 occurs only in the + Y direction. Thus, the contact part 20 is stationary while the contact part 21 rotates in the first direction. Fig. 6 shows the X-axis and Y-axis drive signals generated by the first and second coding groups 2 , 2 'in the (+ Y <X = 0) status. As shown and with further reference to FIG. 6, because the contact member 20 is stationary, the associated rotatable member 23 does not rotate, thereby maintaining the front circuit board and the rear circuit board 240 , 242 in the high logic state due to the connection the latter with the positive (or Vcc) connection of a power supply unit. On the other hand, because the con tact part 21 rotates in the first direction, the associated rotatable part 23 rotates such that the contact arms 230 successively touch the front circuit board 240 . Since the rotatable member 23 is electrically connected to the ground terminal of a power supply unit, the logic state of the front circuit board 240 changes from high to low the moment one of the contact arms 230 comes into contact with it. Thus, due to rotation of the rotatable member 23 with the contact member 21 in the first direction, the + Y-axis drive signal is generated by the second coding group 2 'in the form of a pulse train having equidistant pulses at that time.
  In the example of FIG. 6, the + Y-axis drive signal from the second coding group 2 'is formed by nine consecutive pulses. The number of pulses in the + Y-axis drive signal from the second coding group 2 'depends on the speed of movement of the ball bearing 15 in the + Y direction. The faster the movement of the ball bearing 15 in the + Y direction, the narrower the pulses in the + Y-axis drive signal from the second coding group 2 ', and the greater the number of pulses in the + Y-axis Driver signal.
  The rotational speed of the contact parts 20 , 21 depends on the vectorial angular component of the movement of the ball bearing 15 , which acts on the corresponding contact part 20 , 21 . For example, if the vectorial angular components acting on the contact parts 20 , 21 are the same, the contact parts 20 , 21 will rotate at the same speed. If the vectorial angular component acting on the contact part 20 is larger than that acting on the contact part 21 , then the contact part 20 rotates at a higher speed than the contact part 21 . Accordingly, when the vectorial angular component acting on the contact part 20 is smaller than that acting on the contact part 21 , the contact part 20 rotates at a lower speed than the contact part 21 .
• 2. In the (-Y = + X) state of FIG. 5, movement of the ball bearing 15 occurs in both the -Y direction and the + X direction. Thus, contact part 20 rotates in the first direction, whereas contact part 21 rotates in the second direction. Fig. 7 shows the X-axis and Y-axis drive signals generated by the first and second coding groups 2 , 2 'under the (-Y = + X) state. As shown, both the X-axis drive signal and the -Y-axis drive signal from the first and second coding groups 2 , 2 'are in the form of pulse trains. However, since the vectorial angular components of the movement of the ball bearing 15 acting on the contact parts 20 , 21 are the same, assuming that the ball bearing 15 moves at the same speed as in the example of Fig. 6, the contact parts rotate 20 , 21 at a lower speed than in the example of FIG. 6, which results in wider pulses for the + X-axis and the -Y-axis drive signals.
• 3. In the (+ Y = 0 <X) state of FIG. 5, movement of the ball bearing 15 occurs only in the + X direction. Thus, contact part 21 is stationary, while contact part 20 rotates in the first direction. Fig. 8 shows the X-axis and Y-axis drive signals generated by the first and second coding groups 2 , 2 'in the (+ Y = 0 <X) state. As shown, the Y-axis drive signal from the second coding group 2 'is kept at the logic high state, whereas the + X-axis driving signal from the first coding group 2 is in the form of a pulse train.

Referring to Fig. 9, the pin body 10 is further formed with a Mon animal hole 17 . A positioning frame portion 18 extends inwardly and integrally from the pin body 10 adjacent to the mounting hole 17 . A circuit card 37 is arranged on the positioning frame 18 and has a control unit 3 provided thereon.

The energy supply unit 31 can be in the form of series-connected battery cells (not shown) and provides the electrical energy required for operating the control unit 3 .

Referring to FIG. 10A, the memory device 32 is configured to include at least a computer code storage area 321 , a dictionary database area 322 , a directory storage area 323, and a computing area 324 . The computer code storage area 321 is used to store character patterns and associated standard computer codes that are assigned to characters that are formed on a writing surface by means of the ball bearing 15 . An example of a standard computer code is ASCII, which is suitable for coding alphanumeric characters. However, in view of the fact that some languages, such as. B. Chinese and Japanese, not using ASCII to encode their characters, more than one type of character patterns and standard computer codes can be stored in the area 321 to enable operation of the pen computer 1 under different language formats. The dictionary database area 322 is used to store information regarding the words of a language. The information may include the meaning of a word or a translation of the word into another language, e.g. B. English to Chinese. Known dictionary databases of the aforementioned type in electronic form are applicable in the dictionary database area 322 . The directory storage area 323 is used to store a telephone directory database therein. The format of the directory storage area 323 may be similar to that found in most conventional handheld electronic devices, such as. B. electronic dictionaries and digital personal assistants. The computing section 324 is used for temporarily storing data when performing calculations, identifying an input character, making an entry in the telephone directory database, etc.

In the preferred embodiment, storage device 32 is implemented using various types of storage devices. The first storage unit is a random access memory (FLASH), which has at least the computer code storage area 321 , the dictionary database area 322 and the directory storage area 323 . The second memory unit is a static memory with random access memory, which has at least the computing area 324 .

Referring again to FIG. 10, the dispenser 34 is preferably in the form of a liquid crystal display (LCD) unit that is secured in the mounting hole 17 of the pen body 10 . The alarm tone generator 35 is in the form of a speaker and the switch assembly 36 is used to control the operating mode of the processor 33 , as described in more detail in the following sections.

As shown in FIGS. 10 and 10B, the processor 33 , such as a microprocessor, is connected to the power supply unit 31 , the storage device 32 , the output device 34 , the alarm tone generator 35 and the switch arrangement 36 . The processor 33 is further connected to the first and second coding groups 2 , 2 '(see FIG. 1) in order to receive the X-axis and Y-axis drive signals from there. Referring to FIG. 10B, the processor 33 is configured to have a character recognition unit 331 , an electronic clock unit 332 , an arithmetic unit 333 , a dictionary search unit 334 , a telephone directory management unit 335 and an output driver unit 336 .

Fig. 11 is a flow chart illustrating the operation of the first preferred exporting approximately form. With additional reference to FIGS. 1, 10, 10A and 10B, when the power supply 31 is active, the switch assembly 36 can be operated in a predetermined manner to select the operating mode of the processor 33 and the operating language of the pen computer 1 . Once the ball bearing 15 moves to form characters on a writing surface, the first and second coding groups 2 , 2 'generate the X-axis and Y-axis drive signals in accordance with the detected movement of the ball bearing 15 . At this time, the character recognition unit 331 retrieves the appropriate character patterns and standard computer codes from the computer code storing area 321 of the storage device 32 and stores them in the computing area 324 such that calculations and comparisons can be made to identify those on the writing surface formed characters and the generation of computer codes associated with the characters identified thereby begin. The generated computer codes for the identified characters are stored in the computing area 324 at this time. The character recognition unit 331 is also operatively assigned to the output driver unit 336 , which enables the output device 34 to display the characters identified by the character recognition unit 331 there.

Regarding the way in which the character recognition unit 331 identifies the characters which are formed on the writing surface by means of the ball bearing 15 , this can be achieved using known character recognition techniques which vary according to the languages of the characters to be identified.

When using the pen computer 1 to calculate the result of an arithmetic expression, the switch arrangement 36 is initially operated to start the operation of the processor 33 in a computing mode. When the characters representing the arithmetic expression are written on the writing surface via the ball bearing 15 , the character recognizing unit 331 continues to store the computer codes for the identified characters in the arithmetic area 324 . The arithmetic unit 333 then processes the computer codes stored by the character recognition unit 331 to calculate the result of the arithmetic expression. This action can be triggered upon detection of the computer code for the "=" sign. The computing unit 333 is also operatively associated with the output driver unit 336 , which enables the output device 34 to display the result of the arithmetic expression there.

Fig. 12 is a flowchart illustrating the operation of the processor 33 in the computing mode. Since the functions assigned to the processor 33 in operation in this mode are similar to those found in conventional computers, a detailed explanation of the flow diagram of FIG. 12 is omitted here for reasons of conciseness.

When using the pen computer 1 to search for information regarding a particular word, the switch assembly 36 is initially operated to begin operating the processor 33 in a dictionary search mode. When the characters constituting the specific word are written on the writing surface via the ball bearing 15 , the character recognition unit 331 proceeds to store the computer codes for the identified characters in the computing area 324 . The dictionary search unit 334 then processes the computer codes stored by the character recognition unit 331 to determine the word corresponding to the computer codes, and retrieves the information corresponding to the word thereby determined from the dictionary database area 322 of the storage device 32 from. This action can be triggered upon detection of the computer code for the "?" Character, which is added to the characters of the word in question. The dictionary search unit 334 is also operatively associated with the output driver unit 336 , which enables the output device 34 , which by to display the dictionary search unit 334 information retrieved from the dictionary database area 332 there.

As is known in the art, the procedure for determining a specific word from computer codes varies according to the selected operating language of the pen computer 1 . Since the search routine assigned to the dictionary search unit 334 is generally found in electronic dictionaries, a detailed description thereof is omitted here for the sake of brevity.

Switch assembly 36 may also be operated to enable processor 33 to operate in a directory management mode. The directory management mode, a name and an associated con tact can number in the list storage area 323 are added, and the contact number that is associated with a given name can be retrieved from the directory storage area 323rd When an entry is added to the directory storage area 323 , the characters constituting the name and the contact number associated with the name are written down on the writing surface via the ball bearing 15 . The character recognition unit 331 continues to store the computer codes for the identified characters in the arithmetic area 324 as previously described. The telephone directory management unit 335 then processes the computer codes stored by the character recognition unit 331 to determine the name and the contact number according to the computer codes. The telephone directory management unit 335 is also operatively associated with the output driver assembly 336 , which enables the output device 34 to provide the name and contact number determined by the telephone directory management unit 335 for verification. Upon operation of the switch assembly 36 to verify the accuracy of the information provided on the output device 34 , the telephone directory management unit 335 stores the name and contact number as a new entry in the directory storage area 323 .

When searching for a contact number in the directory storage area 323 , the characters that form an input name are written down on the writing surface via the ball bearing 15 . The character recognition unit 331 proceeds to store the computer codes for the identified characters in the computing area 324 , and the telephone directory management unit 335 then processes the computer codes stored by the character recognition unit 331 to determine the entered name according to the computer codes. By attaching a symbol such as. Of the entered name, upon detection of the symbol, the telephone directory management unit 335 is caused to search the directory storage area 323 for the contact number associated with the entered name. With the support of the output driver unit 336 the output device 34 causes the inputted name and the associated contact number retrieved by the telephone directory management unit 335 to be indicated thereon.

Since known directory construction and directory search techniques found in handheld electronic devices are applicable to the directory management unit 335 , a more detailed description of the operation of the latter is omitted here for brevity.

Switch assembly 36 may also be operated to allow processor 33 to operate in a clock mode. In the clock mode, the electronic clock unit 332 is caused to generate a time output. The electronic clock unit 332 is operatively assigned to the output driver unit 336 in order to allow the output device 34 to indicate the time output of the electronic clock unit 332 there. As with conventional electronic watches, it enables the switch assembly 36 to be operated in a predetermined manner while the processor 33 is in the clock mode, to set the time output of the electronic clock unit 332, and to set an alarm time. In addition, upon detection by the electronic clock unit 332 that the time output has reached the preset alarm time, the electronic clock unit 332 activates the alarm tone generator 35 in a known manner to produce an alarm tone output.

Referring again to FIGS. 10 and 10B is in the preferred exporting the processor approximate shape 33 further configured to receive a Leistungsverwal processing unit 337 have, which is operatively associated with the memory device 32 such that, when the power for the pen-based computer 1 is switched off or if the remaining power of the power supply unit 31 is insufficient to ensure normal operation of the control unit, the power management unit 337 data such as. B. a name and the associated contact number from which static RAM will transfer into the FLASH RAM to avoid data loss.

The configuration of the first and second coding groups should not be limited to that described above. Other forms of coding groups can be used in the pen computer of this invention, as shown in FIGS. 13 and 14.

Fig. 13 illustrates a rotating part 23 a and a sensor unit 24 a of a coding group according to the second preferred embodiment of a pen computer according to the present invention. The rotating part 23 a is made of plastic and has a central fastening section 232 a, which is fixedly arranged on the rotary shaft (not shown), and a number of equally spaced shielding arms 230 a, the supply section radially and outwardly from the central fastening 232 a extend. The sensor unit 24 a has first and second photodetectors (T1), (T2), such as phototransistors, which are mounted on the frame part (not shown) in a side-by-side relationship in the vicinity of the rotating part 23 a. When the rotating shaft rotates in the first direction, each of the shield arms 230 a shields the first photodetector (T1) first, before the second photodetector (T2) is shielded. Thus, the driver signal changes from the first photodetector (T1) to a logic high state before that of the second photodetector (T2). If the rotating shaft rotates in the opposite second direction, each of the shield arms 230 a shields the second photodetector (T2) first, before the first photodetector (T 1) is shielded. The driver signal thus changes from the second photodetector (T2) to a logic high state before that of the first photodetector (T1). If the rotating shaft is not rotating, the first and second photo detectors (T1), (T2) are not shielded by the shielding arms 230 a and generate a corresponding drive signal which is kept at the logic low state.

Fig. 14 illustrates a rotating part 23 b and a sensor unit 14 of a Kodiervor direction according to a third preferred embodiment of a pen computer according to the present invention. The rotary member 23 b has a central attachment portion 232 b that is fixedly attached to the rotary shaft (not shown), and a number of equally spaced arms 230 b that extend radially and outwardly from the central attachment portion 232 b. Each of the arms 230 b has a permanent magnet thereon. Each of the arms me 230 b is preferably formed from a permanent magnet material. The sensor unit 24 b includes first and second Hall effect sensors (S1), (S2), which (not shown) on the frame part are mounted b in the vicinity of the rotating part 23 in a side-by-side relationship. When the rotating shaft rotates in the first direction, each of the arms 230 b moves close to the first Hall effect sensor (S1) first before moving near the second Hall effect sensor (S2). Thus, the driver signal changes from the first Hall effect sensor (S1) to a logically high state before that of the second Hall effect sensor (S2). When the rotating shaft rotates in the opposite second direction, each of the arms 230 b moves close to the second Hall effect sensor (S2) first before moving near the first Hall effect sensor (S1 ) emotional. The driver signal thus changes from the second Hall effect sensor (S2) to a logically high state before that of the first Hall effect sensor (S1). When the rotating shaft is not rotating, the first and second Hall effect sensors (S1), (S2) are not influenced by the magnetic properties of the arms 230 b and generate a corresponding drive signal which is kept at the logic low state.

Claims (21)

1. pen computer ( 1 ), characterized by :
an elongated pen body ( 10 ) having a writing end which is provided with a rotatable ball bearing ( 15 ) which serves as a ballpoint pen tip ( 16 ), the pen body ( 10 ) being designed to be held in one hand for Forming characters on a writing surface over the ball bearing ( 15 );
a first coding group ( 2 ), arranged on the writing end of the pen barrel ( 10 ), for coding movement of the ball bearing ( 15 ) along an X direction and for generating X-axis drive signals in accordance with coded movement of the ball bearing ( 15 ) along the X direction;
a second coding group ( 2 '), arranged on the writing end of the pen trump ( 10 ), for coding movement of the ball bearing ( 15 ) along a Y direction and for generating Y-axis drive signals accordingly coded movement of the ball bearing ( 15 ) along the Y direction; and
Character recognition means ( 331 ) disposed in the pen barrel ( 10 ) and electrically connected to the first and second coding groups ( 2 , 2 ') for receiving the X-axis and Y-axis drive signals therefrom, the character recognition means ( 331 ) identify the characters that are formed on the writing surface via the ball bearing ( 15 ) from the X-axis and Y-axis driver signals and generate computer codes which are assigned to the characters identified here by characters. 2. pen computer ( 1 ) according to claim 1, further characterized by an output device ( 34 ), arranged on the pen body ( 10 ), and by an output driver unit ( 336 ), arranged in the pen body ( 10 ) and connected to the Output device ( 34 ), wherein the character recognition means ( 331 ) are operatively associated with the output driver unit ( 336 ) to enable the output device ( 34 ) to display the characters identified by the character recognition means ( 331 ). 3. pen computer ( 1 ) according to claim 2, characterized in that the output device ( 34 ) is a display unit for visual indication of the characters identified by the character recognition means ( 331 ). 4. pen computer ( 1 ) according to claim 3, further characterized by electronic clock means ( 332 ), which are arranged in the pen body ( 10 ) for generating a time output, wherein the electronic clock means ( 332 ) operatively the output driver unit ( 336 ) are assigned to enable the output device ( 34 ) to indicate the time output of the electronic clock means ( 332 ). 5. pen computer ( 1 ) according to claim 4, further characterized by an alarm tone generator ( 35 ) arranged in the pen body ( 10 ) and connected to and controlled by the electronic clock means ( 332 ) to generate an alarm sound output as determined by the electronic clock means ( 332 ) that the time output of it has reached a preset alarm time. 6. pen computer ( 1 ) according to claim 1, characterized in that the characters formed on the writing surface correspond to an arithmetic expression ent, the pen computer ( 1 ) further comprising computing means ( 333 ) which in the pen body ( 10 ) are arranged and associated with the character recognition means ( 331 ), the computing means ( 333 ) being operative to process the computer codes associated with the characters identified by the character recognition means ( 331 ) to calculate a result of the arithmetic expression. 7. pen computer ( 1 ) according to claim 6, further characterized by an output device ( 34 ) which is arranged on the pen body ( 10 ), and by an output driver unit ( 336 ) which is arranged in the pen body ( 10 ) and is connected to the output device ( 34 ), the computing means ( 333 ) further being operatively associated with the output driver unit ( 336 ) to enable the output device ( 34 ) to indicate the result of the arithmetic expression. 8. pen computer ( 1 ) according to claim 7, characterized in that the output device ( 34 ) is a display unit for visual indication of the result of the arithmetic expression. 9. pen computer ( 1 ) according to claim 1, further characterized by:
a dictionary database ( 322 ) located in the pen barrel ( 10 ) for storing information regarding the words of a language, and
Dictionary search means ( 334 ) arranged in the pen barrel ( 10 ) and the character recognition means ( 331 ) and the dictionary database ( 322 ) assigned, the dictionary search means ( 334 ) being operative to process the computer codes which the by the Character recognition means ( 331 ) are assigned to identified characters in order to determine a word corresponding to the computer codes and to retrieve the information corresponding to the word determined thereby from the dictionary database ( 322 ). 10. pen computer ( 1 ) according to claim 9, further characterized by an output device ( 34 ), which is arranged on the pen body ( 10 ), and by an output driver unit ( 336 ), which is arranged in the pen body ( 10 ) and connected to the output device ( 34 ), the dictionary search means ( 334 ) being further operatively associated with the output driver unit ( 336 ) to enable the output device ( 34 ) through the dictionary search means ( 334 ) from the dictionary database ( 322 ) specify the information retrieved. 11. pen computer ( 1 ) according to claim 10, characterized in that the output device ( 34 ) is a display unit. 12. pen computer ( 1 ) according to claim 1, characterized in that the characters formed on the writing surface correspond to a name and a name assigned to the contact name, the pen computer ( 1 ) further comprising:
a directory storage unit ( 323 ) located in the pen body ( 10 ) for storing a telephone directory database therein; and
Telephone directory management means ( 335 ) arranged in the pen barrel ( 10 ) and associated with the character recognition means ( 331 ) and the dictionary memory unit ( 323 ), the telephone directory management means ( 335 ) being operatively in a directory construction mode to process the computer codes which are assigned to the characters identified by the character recognition means ( 331 ) in order to determine the name and the contact number in accordance with the computer codes and to store the name and the contact number here determined in the directory storage unit ( 323 ). 13. pen computer ( 1 ) according to claim 12, further characterized in that the telephone directory management means ( 335 ) are further operative in a directory search mode in which the telephone directory management means ( 335 ) process the computer codes which by the Character recognition means ( 331 ) are assigned to identified characters to determine the name according to the computer codes, and the directory storage unit ( 323 ) searches for the contact number assigned to the name. 14. pen computer ( 1 ) according to claim 13, further characterized by an output device ( 34 ) arranged on the pen body ( 10 ), and by an output driver unit ( 336 ) arranged in the pen body ( 10 ) and connected to the output device ( 34 ), the telephone directory management means ( 335 ) being further operatively associated with the output driver unit ( 336 ) to enable the output device ( 34 ) to be separated from the directory storage unit ( 323 ) by the telephone directory management means ( 335 ). specify the contact number called. 15. pen computer ( 1 ) according to claim 14, characterized in that the output device ( 34 ) is a display unit. 16. pen computer ( 1 ) according to any one of the preceding claims, further characterized by ink supply means ( 14 ), which are arranged in the pen body ( 10 ) for supplying the ball bearing ( 15 ) with ink. 17. pen computer ( 1 ) according to any one of the preceding claims, characterized in that each of the first and second coding groups ( 2 , 2 ') comprises:
a frame part ( 22 ) which is firmly arranged on the writing end of the pen barrel ( 10 );
a rotatable shaft ( 220 ) rotatably disposed on the frame member ( 22 );
a contact part ( 20 , 21 ) which is fixedly arranged on the rotatable shaft ( 220 ) and is in contact with the ball bearing ( 15 ) such that rotation of the ball bearing ( 15 ) a corresponding rotation of the rotatable shaft ( 220 ) be can work;
a rotatable part ( 23 , 23 a, 23 b) which is fixedly arranged on the rotatable shaft ( 220 ) for rotation therewith; and
a sensor unit ( 24 , 24 a, 24 b), which is fixedly arranged on the frame part ( 22 ), for generating the driver signals in response to a detected movement of the rotatable part ( 23 , 23 a, 23 b). 18. pen computer ( 1 ) according to claim 17, characterized in that
the rotatable part ( 23 ) is designed as a conductive part which has a central mounting section ( 232 ) which is fixedly arranged on the rotatable shaft ( 220 ) and a number of equally spaced contact arms ( 230 ) which extend radially and laterally extend from the central mounting portion ( 230 ), the rotatable member ( 23 ) being adapted to be electrically connected to a power source; and
wherein the sensor unit ( 24 ) has an insulator substrate ( 241 ) and front and rear printed circuit boards ( 240 , 242 ), which are arranged on front and rear sides of the insulator substrate ( 241 ), the insulator substrate ( 241 ) on the frame part ( 222 ) is arranged in the vicinity of the rotatable part ( 23 ) that rotation of the rotatable shaft ( 220 ) in a first direction enables the contact arms ( 230 ) to successively touch the front circuit board ( 240 ) and that rotation of the rotatable Shaft ( 220 ) in an opposite second direction allows the contact arms ( 230 ) to successively touch the rear circuit board ( 242 ). 19. pen computer ( 1 ) according to claim 17, characterized in that
the rotatable part ( 23 a) has a central mounting section ( 232 a) which is fixedly arranged on the rotatable shaft ( 220 ), and a number of equally spaced protective arms ( 230 a) which are radially and outwardly from the center Extend mounting section ( 232 a) has; and
wherein the sensor unit ( 24 a) has first and second photodetectors (T1, T2) which are arranged on the frame part ( 22 ) in a side-by-side relationship in the vicinity of the rotatable part ( 23 a), such that that rotation of the rotary shaft ( 220 ) in a first direction enables each of the shield arms ( 230 a) to shield the first photodetector (T1) before shielding the second photodetector (T2) and such that rotation of the rotary shaft ( 220 ) in an opposite second direction enables each of the shielding arms ( 230 a) to first shield the second photodetector (T2) from shielding the first photodetector (T 1). 20. pen computer ( 1 ) according to claim 19, characterized in that he most and second photo detectors (T1, T2) are phototransistors. 21. pen computer ( 1 ) according to claim 17, characterized in that
the rotatable part ( 23 b) has a central mounting section ( 232 b) which is fixedly arranged on the rotatable shaft ( 220 ), and a number of equally spaced arms ( 230 b) which extend radially and outwards from the central mounting section ( 232 b), each of the arms ( 230 b) having a permanent magnet thereon; and
wherein the sensor unit ( 24 b) has first and second Hall effect sensors (S1, S2) which are arranged on the frame part ( 22 ) in a side-by-side relationship in the vicinity of the rotatable part ( 23 b) such that rotation of the rotatable shaft ( 220 ) in a first direction enables each of the arms ( 230 b) to move close to the first Hall effect sensor (S1) before moving next to the second Hall effect sensor. Sensor (S2) and such that rotation of the rotatable shaft ( 220 ) in an opposite second direction enables each of the arms ( 230 b) close to the second Hall effect sensor (S2) to move first before moving next the first Hall effect sensor (S1).