DE4206666A1 - METHOD FOR PROCESSING THE SCAN, DETECTING PHANTOM BUTTONS AND CONTROLLING THE LED INDICATOR LAMPS IN A KEYBOARD INTERFACE BY MEANS OF TIMING TO IMPROVE THE PROCESSING TIME, THE CAPACITY OF THE INDIVIDUAL CHIPS AND THE FIRMWARE TO THE FIRMWARE - Google Patents

Abstract

A keyboard for a computer includes plural indicators (LED1, LED2, LED3) having a common terminal (40), the common terminal being selectively alternatively connectable directly to a supply terminal (Vcc), or via a gating means (T1) to said supply terminal (Vcc). The keyboard may include a control device for producing a periodic enabling signal at an output (S12) thereof so that if the common terminal (40) is connected to the supply terminal via the gating means (T1), the output (S12) controls the gating means (T1) to provide time division operation of the indicators. Alternatively, when the common terminal is directly connected to the supply terminal (Vcc), the output of said control device is coupled to a scanning line of the keyboard. The output of the control device may be coupled to an audible signalling means for operation thereof by the periodic enabling signal. <IMAGE>

Description

Ordinary computer keyboards usually have one of the three hardware arrangements shown in FIGS. 11 to 13. There are two types of standard keyboards (IBM compatible), namely one with 101 keys and a second with 102 keys. When designing a circuit for a standard keyboard that can use the variable scan code, at least 103 keys must be provided. Furthermore, a keyboard has at least three LED indicator lamps, namely first Num Lock, second Scroll Lock and third Caps Lock.

The hardware arrangement shown in Fig. 11 uses the known firmware technique to add a decoder to the scan port to expand the scan lines. With this hardware arrangement, independent control lines are provided for separate control of the three LED indicator lamps. The main disadvantage of this hardware arrangement is that the decoder increases the price of the keyboard. The main advantage of this hardware arrangement is that the LED indicator lamps are controlled separately and there are no interactions with other output lines. Another advantage of this hardware arrangement is that this keyboard can scan 120 keys (15 x 8 = 120).

The hardware arrangement in FIG. 12 uses the known firmware technology to add a transistor to the LED indicator lamps. This arrangement does not use a decoder in the scan port. The transistor does not work during the scanning process and at the moment when the LED indicator lamps are off. As soon as a scanning process is completed, the transistor works immediately and the LED indicator lamps are therefore switched to the existing operating mode. The main advantage of this hardware arrangement is that the cost of a decoder is avoided. The main disadvantage of this hardware arrangement is that the LED indicator lamps only light up with low intensity because the transistor is switched on and off periodically. Another disadvantage of this hardware arrangement is that the keyboard can only scan 104 keys (8 * 13 = 104).

The hardware design shown in Fig. 13 is also an application of known firmware technology. In comparison to the hardware arrangement of FIG. 12, this hardware arrangement does not require a transistor and connects the positive connection of each LED indicator lamp to the positive connection of the power supply. Acer Corporation filed a Taiwanese application (No. 7 72 04 894) on May 25, 1988 in which the circuit shown in Fig. 12 is applied and no transistor is required. According to Acer's application, suitable firmware has to be adapted so that the user can accept the arrangement and effects similar to the hardware arrangements of FIGS. 11 and 12 can be achieved.

However, Acer does not disclose any modification or improvement to the firmware. It's just about the phenomenon of permanent visibility. Although a change in the status of the LED indicator lamps can be caused during the scanning process, it will be renewed after a certain time interval. Acer explains that users cannot see such a rapid change (in 10 to 20 microseconds) of the status of the LED indicator lamps, that is, from the user's perspective, the LED indicator lamps remain unchanged. In fact, the LED indicator lamps will produce weak light during the scan (if the LED indicator lamps were originally kept in OFF mode). According to a note in Acer's disclosure, what is visible can change with the intensity of the ambient light. Of course, users do not see a change in the status of the LED indicator lamps when the ambient light is high (in direct sunlight). However, any change in the status of the LED indicator lamps will be visible in closed rooms or when the ambient light is not very intense. It is a common method to avoid the aforementioned problem by increasing the resistance of the resistors R1, R2 and R3 in the circuit shown in Fig. 13 up to 390 ohms. By increasing the resistance of the resistors, the normal intensity of the light of the LED indicator lamps is relatively reduced (since the electrical current is reduced) and therefore any change in the status of the LED indicator lamps (which causes the LED indicator lamps to dimly light) will not be readily visible . This method is applicable, but is unsatisfactory in use.

It is an object of the present invention the aforementioned To avoid or reduce disadvantages.

The invention solves this problem by the characterizing Features of claim 1. The present invention can be used for other purposes greatly reduce the memory space of the single chip ren. According to the present invention, an 8049IC  used, and the programmable memory only shows a capacity of 2 K bytes, where each key has three codes contains (SET1, SET2 and SET3) and where the third code (SET3) each key can be set separately to the output code (1), to instruct the make code (2) and the break code (3) with a repeat function or not to show. For this reason, all models can include XT / AT and PS2 compatible and with each other for online Operation. One after the Acer revelation built keyboard provides XT / AT, PS2 with only one key code, which cannot be set separately because there is not enough space is available for such a functional process.

The aspects and the firmware design of the present invention are explained in more detail below with reference to FIGS. 1 to 10. In it show:

Fig. 1 is a circuit diagram showing the keyboard scanning method of the present invention;

Fig. 2 is a cycle diagram showing the change in the status of the LED indicator lamps;

FIGS. 3 to 10 Keyboard software flow diagrams according to the present invention.

According to the present invention, there are 13 basic scan lines intended for scanning 104 keys (8 * 13 = 104), which for a standard keyboard is sufficient.

As shown in Fig. 1, there are two dashed lines (a) and two dashed lines (b) which form four skip lines in the arrangement of a personal computer board (motherboard). If the two jump lines (b) are connected, the jump lines (a) should not be connected, ie (a) and (b) should not be connected at the same time, therefore two different circuit connection methods are available. When the two dashed lines (b) are connected, the circuit corresponds to the circuit of Fig. 12. In this arrangement, as will be explained later, a special firmware processing technique for controlling the scanning of the keyboard, the detection of phantom keys and the status update of the LED indicator lamps applied by time division. This method can completely eliminate the disadvantage of weak light. If the two skip lines (a) are connected, an additional control line is available for scanning purposes or to control a buzzer, the LED indicator lamps are then connected directly to the power supply. In this arrangement, a special firmware processing technique for controlling the scanning of the keyboard, the detection of phantom keys and the status renewal of the LED indicator lamps by means of time division is also applied, so that the disadvantage of the low light is completely eliminated. If the additional control line is used for scanning, 112 keys can be scanned (8 * 14 = 112). If the additional control line is used to control a buzzer, a key switch can be adapted to control a buzzer so that it generates a Ge noise from two segments, ie a "click-click" sound.

The firmware design of the present invention will follow the explained.

Because an instruction from a single chip within a fixed Time interval must be executed, the mode of LED indicator lamps shown changed when the status of the common connections for the LED control line and the scan line changes. The LED indicator lamps will be returned to its original status when a scan process is finished. The key to avoiding the after part of the dim light lies in the application of the the reduced sampling time saved time (i.e. the time taken to which the status of the LED indicator lamps changed temporarily becomes). The firmware design of the present invention is such  that all judging jobs before the change the scan lines are completely terminated so that immit the status of all after the change of the scan lines Keys read and the status of the LED indicator lamps renewed becomes. The execution time is 5 to 10 microseconds.

If the time in which the status of the LED indicator lamps is changed temporarily is to be shortened, the disadvantage of the low light can be avoided, but the effect of independent control lines as shown in Fig. 11 may not be achieved. The total sampling time should therefore be structured appropriately. The present invention employs a time division technique where 4 milliseconds are defined as the basis so that each scan line is scanned once every 260 microseconds, with seven scan lines being scanned in one cycle and 4 milliseconds being defined as one cycle. The actual total sampling time is therefore 1.82 milliseconds (260 x 7 = 1820), while the remaining time is 2.18 milliseconds. It takes two cycles (4 x 2 = 8 milliseconds) to have all scan lines complete a scan. However, there are only three scan lines that control the LED indicator lamps while the scan is in progress. There are therefore three options for changing the status of the LED indicator lamps within two cycles.

Reference is made to FIG. 2. It shows that there are three possibilities for changing the status of the LED indicator lamps within two cycles, each lasting 5 to 10 microseconds. In comparison with two cycles, 8 milliseconds is therefore very long compared to 5 to 10 microseconds (the time interval in which the status of the LED indicator lamps changes temporarily). The resistance of resistors R1, R2 and R3 in the circuit shown in FIG. 13 can therefore be reduced to approximately 220 ohms in order to increase the intensity of the light of the LED indicator lamps. With this arrangement, the human eye cannot detect any change in the status of the LED indicator lamps, and therefore the effect of the three independent control lines for controlling the LED indicator lamps as shown in Fig. 11 can also be achieved by the present invention.

The firmware program of the present invention is now explained using the following flowcharts.

Fig. 3 Start time delay, includes stacking the start code in the buffer and setting the flag for the repeat function.

Fig. 4 At step G1 it can be seen that when a mother button and one of the daughter buttons 1 to 5 are pressed, the speed for the repeat function is renewed when five different values have been set in the flag for the repeat function. At step F, it can be seen that when a key is pressed after the buzzer control line is set to HIGH status, a "click-click" sound is generated. The buzzer stops generating noise when the processing procedure reaches step F. The noise duration is 2 milliseconds ± 20%.

Fig. 5 denotes a XXH given by the system to the keyboard command in the form of a hexadecimal code. Upon receipt of such an instruction from the system, the keyboard operates in accordance with the instructions received. Examples:
FOH for setting the module code,
EEH to send the reply code,
F2H for sending the set code,
FFH to reset the keyboard etc.

Fig. 6 If the keyboard sets data and clock to HIGH while sending a code, the potential of both data and clock must be detected again immediately. If any condition opposite to HIGH is detected, it should be considered a transmission error and the keyboard should stop sending the code and return to the network processing program.

Fig. 7 If the buzzer flag is set, the buzzer control line should be brought into the enable state, ie the buzzer control line should be set to high potential. On the other hand, the buzzer control line should be set to low potential if the buzzer flag is not set.

Claims (2)

1. A method of processing of scanning, the detection of phantom key and the control of LED indicator lamps in a keyboard interface, characterized by the appli cation of time-division, as shown in FIG. 1, the shown in Fig. 1 two dashed lines (a) and the two dashed lines (b) form four jumper wires of a personal computer board (personal computer main board), and either the two jumper wires (a) or the two jumper wires (b) are connected, so that two different circuit connection methods are available In one of these methods, the two jumper wires (b), as shown in FIG. 12, are connected to form a circuit and a firmware processing technique for controlling the scanning of the keyboard, the detection of phantom keys and the change in the status of the LED indicator lamps by means of time division is adjusted, and wherein in the other of the two circuit connection processing methods two jumper wires (a) are connected to a circuit which has an additional control line for scanning purposes or for controlling a buzzer, in which case the LED indicator lamps are connected directly to a power supply, and wherein a firmware processing technique for controlling the scanning of the keyboard, the Detection of phantom buttons and the change in the status of the LED indicator lamps is adjusted by means of time division, with the help of the additional control line 112 keys (8 * 14 = 112) can be scanned if it is used for scanning purposes or this additional control line to a key conductor is adjusted to control a buzzer for generating a key noise. 2. The method according to claim 1, characterized by using the firmware processing technology shown in FIGS. 3 to 9 for controlling the scanning of the keyboard, the detection of phantom keys and the change in the status of the LED indicator lamps by means of time division.