JP3658151B2 - Printing device and printing method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a printing apparatus, a printing method, and a storage medium that perform printing by exchanging data with a host computer by a handshake method.
[0002]
[Prior art]
Normally, a printing device (printer) using a Centronics-compliant interface receives print data (including printer control commands) from the host computer at the timing of the STBX (strobe) signal, BUSY (receiving), ACKX (reception completed) The print data is sequentially received from the host computer and printed by the handshake method in which the next print data is received by returning a signal to the host computer.
[0003]
In the conventional data transfer, the data processing capability of the host computer or printer is low, and the data transfer rate is as low as about 20 μS per byte as shown in FIG. For this reason, the width of the ACKX signal returned from the printer to the host computer is determined to be about 4 μS in consideration of the data transfer rate and the processing time by the noise countermeasure filter during communication. It was.
[0004]
[Problems to be solved by the invention]
By the way, in recent years, as the resolution of a printer increases, the amount of data for printing also increases, and an improvement in data transfer speed is desired. In addition, the data processing capability of the host computer or printer has been remarkably improved with the speeding up of the CPU and memory. Usually, since data reception from the host computer is performed by DMA, after receiving the STBX signal at the timing t2 shown in FIG. 9, it takes only about 300 nS to return the BUSY signal at the timing t3. It takes only about 200 nS from the start of data acquisition at the timing t3 to the end of the data acquisition at the timing t4. That is, the printer process ends at the timing t4. However, the ACKX signal width of about 4 μS from the timing t4 to the timing t5 becomes a bottleneck, and the improvement of the data transfer rate is suppressed.
[0005]
The present invention has been made under such a background, and an object thereof is to improve the data transfer speed from the host computer to the printer as much as possible in accordance with the performance of the host computer and the printer.
[0006]
[Means for Solving the Problems]
  In order to solve the above-mentioned problem, the invention described in claim 1 has an interface unit for receiving data transferred from a host computer, and performs data transfer with the host computer by handshaking to perform printing. In the printing device,First setting means for setting the ACKX signal width of the ACKX signal to be output when the data transferred from the host computer is received to the first ACKX signal width, and a printing state based on the transferred data is checked. If the printing state is good, the first ACKX signal width is set as is, and if the printing state is bad, the second ACKX is longer than the first ACKX signal width. A second setting means for setting the signal width;It has.
[0007]
  Moreover, in invention of Claim 2, the said of Claim 1 is said.FirstSetting meansThe first ACKX signal width is set according to the operation of the ACKX width setting key, and the second setting means is configured to set the second ACKX signal width according to the operation of the ACKX width setting key..
[0008]
  In addition, the invention according to claim 3Tomorrow,In a printing apparatus that has an interface unit for receiving data transferred from a host computer and performs data transfer with the host computer by a handshake method, the data transferred from the host computer is received. First measuring means for measuring a first data transfer required time in the case of the first ACKX signal width set as the ACKX signal width of the ACKX signal to be output, and a first measuring means shorter than the first ACKX signal width Second measurement means for measuring the second data transfer required time in the case of two ACKX signal widths, the first data transfer required time measured by the first measurement means, and the second measurement means. As a result of comparing the measured second data transfer time, the host computer can recognize the ACKX signal. Without waiting for the ACKX signal, the means for outputting the ACKX signal having the first ACKX signal width, the first data transfer required time measured by the first measuring means, and the second measurement When the host computer cannot recognize the ACKX signal and waits for the ACKX signal as a result of comparing with the second data transfer required time measured by the means, the ACKX signal width of the ACKX signal is set to the second ACKX signal width. And third setting means for setting longer than the ACKX signal width.
[0009]
  In the invention according to claim 4, the claim3ListedThe first measuring means or the second measuring means measures the time required for data transfer by measuring the period of the STBX signal from the host computer.It is configured.
[0010]
  Further, the invention according to claim 5.Tomorrow,In a printing apparatus that has an interface unit for receiving data transferred from a host computer and performs printing by performing data transfer with the host computer by a handshake method,  First measuring means for measuring a first data transfer required time in the case of a first ACKX signal width set as an ACKX signal width of an ACKX signal output when data transferred from the host computer is received; , Second measuring means for measuring the second data transfer required time in the case of the second ACKX signal width shorter than the first ACKX signal width, and the first measuring means measured by the first measuring means. As a result of comparing the data transfer required time with the second data transfer required time measured by the second measuring means, the second data transfer required time is compared with the first data transfer required time. If the ACKX signal becomes extremely long, the ACKX signal having the first ACKX signal width is temporarily output to transfer the next data, and then the ACKX signal is stepped longer than the second ACKX signal width. Determining means for determining the ACKX signal width when the comparison result between the data transfer required time in the case of the above and the first data transfer required time in the case of the first ACKX signal width reaches a level where the ACKX signal can be recognized. And have.
[0011]
  Further, the invention according to claim 6.Tomorrow,In a printing method having an interface unit for receiving data transferred from a host computer and performing printing by exchanging data with the host computer by a handshake method, the data transferred from the host computer is received A first setting step of setting the ACKX signal width of the ACKX signal to be output to the first ACKX signal width, a step of checking the printing state based on the transferred data, and if the printing state is good A second setting step of setting the second ACKX signal width to be longer than the first ACKX signal width if the first ACKX signal width is left set and the printing state is poor. It has.
[0012]
  In the invention according to claim 7, the claim6DescribedThe first setting step sets the first ACKX signal width according to the operation of the ACKX width setting key, and the second setting step sets the second ACKX signal width according to the operation of the ACKX width setting key. Configured to set.
[0013]
  The invention according to claim 8In a printing method having an interface unit for receiving data transferred from a host computer and performing printing by exchanging data with the host computer by a handshake method, the data transferred from the host computer is received A first measurement step of measuring a first data transfer required time in the case of the first ACKX signal width set as the ACKX signal width of the ACKX signal to be output, and a first measurement step shorter than the first ACKX signal width A second measurement step of measuring the second data transfer required time in the case of two ACKX signal widths, the first data transfer required time measured by the first measurement step, and the second measurement step. As a result of comparing the measured second data transfer time, the host computer can recognize the ACKX signal. When waiting for the ACKX signal, the step of outputting the ACKX signal having the first ACKX signal width, the first time required for data transfer measured by the first measurement step, and the second measurement step When the host computer cannot recognize the ACKX signal and is waiting for the ACKX signal as a result of comparing with the second data transfer time measured by the above, the ACKX signal width of the ACKX signal is set to the second ACKX signal width. And a setting step for setting longer than the ACKX signal width.
[0014]
  In the invention according to claim 9, the invention according to claim 8 is provided.The first measuring step or the second measuring step is configured to measure the time required for data transfer by measuring the period of the STBX signal from the host computer.
[0015]
  The invention according to claim 10In a printing method having an interface unit for receiving data transferred from a host computer and performing printing by exchanging data with the host computer by a handshake method, the data transferred from the host computer is received A first measurement step of measuring a first data transfer required time in the case of the first ACKX signal width set as the ACKX signal width of the ACKX signal to be output, and a first measurement step shorter than the first ACKX signal width A second measurement step for measuring a second data transfer required time in the case of two ACKX signal widths; a first data transfer required time measured in the first measurement step; and the second measurement. As a result of comparison with the second data transfer required time measured in the process, the second data transfer required time is the first data transfer required time. If the ACKX signal is extremely longer than the ACKX signal, the ACKX signal having the first ACKX signal width is temporarily output so that the next data can be transferred. The ACKX signal width is determined when the comparison result between the data transfer required time in the case of the ACKX signal width and the first data transfer required time in the case of the first ACKX signal width is such that the ACKX signal can be recognized. And a confirmation step to be performed.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
[First embodiment]
FIG. 1 is a block diagram showing a schematic configuration of a data processing system using a printer according to an embodiment of the present invention. The data processing system includes a host computer 100 and a printer 200.
[0025]
The host computer 100 includes a data processing unit 110 and an interface unit 120. The data processing unit 110 includes a CPU 111, a ROM 112, and a RAM 113, and the interface unit 120 includes a transmission buffer 121, an STBX generation circuit 122, and a BUSY / ACKX detection circuit 123. The CPU 111 of the data processing unit 110 performs various data processing based on a system program stored in the ROM 112, an application program stored in a hard disk (not shown), or the like while using the RAM 113 as a work area.
[0026]
The interface unit 120 is an interface compliant with the Centronics interface, and the transmission buffer 121 in the interface unit 120 temporarily stores data to be printed when a print instruction is given to data processed by the CPU 111. It is used to memorize. The STBX generation circuit 122 is a kind of signal used when data is exchanged with the printer 200 by the handshake method, and indicates that data is output to the data line L1 (that is, the validity of the data). This is a circuit for generating an STBX signal, and this STBX signal is output to the printer 200 via the STBX control line L2. The BUSY / ACKX detection circuit 123 is a BUSY signal (signal indicating reception) returned from the printer 200 via the BUSY control line L3 or ACKX control line L4, or an ACKX detection circuit 123 (signal indicating completion of reception). Is a circuit for detecting
[0027]
The printer 200 includes a print processing unit 210, an interface unit 220, and an operation panel 230. The print processing unit 210 includes a CPU 211, a ROM 212, a development buffer 213, a print buffer 214, and a print head 215. The interface unit 220 includes a reception buffer 221, an STBX detection circuit 222, a BUSY / ACKX generation circuit 223, and an ACKX width variable. The operation panel 230 includes, for example, a liquid crystal touch panel and the like, and includes an ACKX signal in addition to various setting keys (not shown) such as a paper size setting key for setting the paper size. An ACKX width setting key 231 for manually setting the width and an ACKX width setting mode key 232 for setting an ACKX width setting mode for automatically setting an optimum ACKX signal width are provided.
[0028]
The CPU 211 of the print processing unit 210 controls various print processes according to a program stored in the ROM 212. The ROM 212 also stores a program corresponding to the flowchart of FIG. The expansion buffer 213 expands and stores received data related to data compression temporarily stored in the reception buffer 221 and expands and stores the data. The data expanded on the expansion buffer 213 is subjected to predetermined image processing or the like. And temporarily stored in the print buffer 214 and printed by the print head 215.
[0029]
In the reception buffer 221 of the interface unit 220, data to be printed (including printer control commands) transferred from the RAM 113 via the transmission buffer 121 of the host computer 100 and the data line L1 is temporarily stored. The STBX detection circuit 222 is a circuit that detects an STBX signal transmitted from the STBX generation circuit 122 of the host computer 100 via the STBX control line L2, and the BUSY / ACKX generation circuit 223 generates a BUSY signal and an ACKX signal. Circuit. The ACKX width variable circuit 224 is a circuit that changes and controls the ACKX signal width based on a setting operation using the ACKX width setting key 231. The transfer time measuring circuit 225 determines the time required for data transfer from the host computer 100 to the printer 200. This is a circuit for measuring based on the STBX signal.
[0030]
The transfer time measuring circuit 225 and the ACKX width setting mode key 232 are components unique to the third embodiment, and are not necessarily provided in the first and second embodiments. The ACKX width setting key 231 is not necessarily provided. These are constituent elements unique to the first and second embodiments, and are not necessarily provided in the third embodiment.
[0031]
Next, handshake control will be described. When the STBX signal is output from the STBX generation circuit 122 in synchronization with the transfer of data from the transmission buffer 121 of the host computer 100, the printer 200 detects the STBX signal by the STBX detection circuit 222, and this STBX signal. Capture print data in sync with. During reception of print data, after completion of reception of print data, the BUSY / ACKX signal generation circuit 223 outputs a BUSY signal and an ACKX signal, respectively. Then, the host computer 100 detects the BUSY signal and the ACKX signal by the BUSY / ACKX signal detection circuit 123, and transfers the next print data if there is next print data. At this time, the ACKX signal width is controlled by the ACKX width variable circuit 224.
[0032]
Next, data transfer control unique to the first embodiment will be described with reference to the flowchart of FIG.
[0033]
First, the user operates the ACKX width setting key 231 of the printer 200 to set the ACKX signal width to 1 μS (step S201). Next, the user instructs printing on the application program on the host computer 100 to execute printing by the printer 200 (step S202), and uses the ACKX signal having the executed printing state, that is, the signal width of 1 μS. In this case, the state of printing is checked (step S203). As a result, if the printing state is good, the process ends as it is, that is, with the ACKX signal width set to 1 μS. In this case, printing is continued with the ACKX signal width set to 1 μS, the data transfer speed is increased in each stage (see TA in FIG. 5), and high speed is maintained while maintaining a good printing state. Printing can be performed.
[0034]
On the other hand, if the printing state is poor, the ACKX signal width is reset to 4 μS by operating the ACKX width setting key 231 (step S204), and the process is terminated. As a result, since the subsequent data transfer is performed using the ACKX signal having a large signal width of 4 μS, the printing defect is eliminated.
[0035]
As shown in FIG. 7, the cause of the printing failure is that the width of the ACKX signal from the printer 200 is short, so the BUSY / ACKX detection circuit 123 of the host computer 100 cannot detect the ACKX signal, and the next data Cannot be transferred (refer to the DATA2 portion indicated by the broken line in FIG. 7). That is, if the ACKX signal cannot be detected, the host computer 100 continues to wait for the ACKX signal or stops the data transfer due to a time-out. It becomes a state. However, in this embodiment, as described above, when a printing failure occurs, a long ACKX signal width of 4 μS is set, so that the next printing is normally performed.
[0036]
Even when printing is normal, the printing time may not be shortened as a result. This is because the processing capability of the host computer 100 is low, that is, the data transfer rate is inherently slow (see TB in FIG. 6), and even if the ACKX signal width is shortened, It is conceivable that it does not contribute to improvement and that the printing speed of the printer 200 is slower than the data transfer speed from the host computer 100.
[0037]
Therefore, in this embodiment, the ACKX signal width is kept at 1 μS even when the printing time is not shortened despite the normal printing, but the case where the ACKX signal width is set to 4 μS and 1 μS. If the print time is not shortened even if the ACKX signal width is set to 1 μS, it means that the processing capacity of the host computer 100 is low, so the ACKX signal width is set to 4 μS. By correcting the margin, the margin in which the host computer 100 can detect the ACKX signal may be increased.
[0038]
If the data amount is small due to a large data compression rate, the printing time may not be changed due to the limit of the printing speed of the printer 200. The printing time may be measured by executing printing in a printing mode such as a draft mode having a high printing speed.
[0039]
[Second Embodiment]
Next, data transfer control unique to the second embodiment will be described with reference to the flowchart of FIG.
[0040]
First, the user operates the ACKX width setting key 231 of the printer 200 to set the ACKX signal width to 1 μS (step S301). Next, the user instructs printing on the application program on the host computer 100 to execute printing by the printer 200 (step S302), and the executed printing state, that is, the ACKX signal having a signal width of 1 μS is used. In this case, the printing state is checked (step S303). As a result, if the printing state is good, the process ends as it is, that is, with the ACKX signal width set to 1 μS. In this case, printing is continued with the ACKX signal width set to 1 μS, the data transfer speed is increased in each stage (see TA in FIG. 5), and high speed is maintained while maintaining a good printing state. Printing can be performed.
[0041]
On the other hand, if the print state is poor, an ACKX signal width that is longer by 1 μm than before is set by operating the ACKX width setting key 231 (step S304). In this case, in the subsequent data transfer, the ACKX signal width is 2 μS, and in step S302, data transfer is performed using the ACKX signal having the 2 μS width, and printing is executed. Then, the printing state when an ACKX signal having a width of 2 μS is used is checked (step S303). As a result, if the printing state is good, the process is terminated. If the printing state is not good, an ACKX signal width longer by 1 μS than before is set again by operating the ACKX width setting key 231 (step S304).
[0042]
In this way, the ACKX signal width is extended by 1 μS until a satisfactory print result is obtained. In other words, by setting an optimal ACKX signal width according to the performance of the host computer 100 and the printer 200, the data transfer speed from the host computer 100 to the printer 200 is increased as much as possible, and the printing speed is improved. I am letting.
[0043]
In the second embodiment as well, if the printing time is not shortened despite the normal printing, the same measures as in the first embodiment may be taken.
[0044]
[Third embodiment]
Next, data transfer control unique to the third embodiment will be described with reference to the flowchart of FIG.
[0045]
First, the user operates the ACKX width setting mode key 232 of the printer 200 to set the ACKX width setting mode (step S401). Next, the user instructs printing on the application program on the host computer 100 and causes the printer 200 to execute printing (step S402). In the initial state, an ACKX signal width of 4 μS is set for the ACKX width variable circuit 224.
[0046]
When printing is started, the CPU 211 of the printer 200 measures the data transfer required time T1 from the host computer 100 to the printer 200 by the transfer time measuring circuit 225 in accordance with a program preset in the ROM 212 (step S403). That is, in step S403, the data transfer speed when the ACKX signal width is 4 μS is indirectly measured by measuring the data transfer required time T1.
[0047]
Next, the CPU 211 sets the ACKX signal width to 1 μS for the ACKX width variable circuit 224 (step S404). By this setting process, the ACKX width variable circuit 224 controls the BUSY / ACKX generation circuit 223 to generate an ACKX signal having a width of 1 μS. Then, the data transfer required time T2 when the ACKX signal width is 1 μS is measured by the transfer time measuring circuit 225 (step S405).
[0048]
Specifically, the transfer time measuring circuit 225 measures the time required for data transfer (that is, data transfer) by measuring the cycle T (see FIGS. 5 and 6) of the STBX signal supplied from the host computer 100. Speed) T1 and T2 are measured. As described above, in the third embodiment, by measuring the data transfer speed based on the cycle T of the STBX signal supplied from the host computer 100, the change in the data transfer speed is not affected by the printing speed of the printer 200. To measure.
[0049]
Next, the CPU 211 determines whether or not the data transfer time T2 when the ACKX signal width is 1 μS is shorter than the required time (T1 × 10) that is 10 times the data transfer time T1 when the ACKX signal width is 4 μS. Is determined (step S406). Here, when T2 <T1, it means that the data transfer rate is improved by shortening the ACKX signal width to 1 μS. When T2 = T1, the processing capability of the host computer 100 is low. This means that the transfer speed does not change. If T2 ≧ T1 × 10, the width of the ACKX signal from the printer 200 is short as shown by the DATA2 portion indicated by the broken line in FIG. 7, and the host computer 100 cannot recognize the ACKX signal and does not recognize the ACKX signal. It means that the next data cannot be transmitted because it is waiting for a signal.
[0050]
In this embodiment, when the host computer 100 can recognize the ACKX signal, that is, when it is determined in step S406 that T2 <T1 × 10, the ACKX signal width setting mode is terminated, and ACKX is used in the subsequent data transfer. The signal width is 1 μS. On the other hand, if it is determined in step S406 that T2 ≧ T1 × 10 and the host computer 100 cannot recognize the ACKX signal and cannot transmit the next data, the CPU 211 indicates the timing t7 to T8 in FIG. As described above, by outputting the ACKX signal and the BUSY signal having a width of 4 μS, the host computer 100 can reliably recognize the ACKX signal and transmit the next data (step S407).
[0051]
Normally, the timeout time during the handshake operation of the host computer 100 is about several seconds. However, the delay of the ACKX signal in the present embodiment is at most (4 μS × 10 + 4 μS) wide ACKX signal and data acquisition time ( Since the total value is usually shorter than the timeout time, timeout control is not actually performed.
[0052]
After outputting the 4 μS width ACKX signal and BUSY signal in step S407, the CPU 211 sets the ACKX signal width of 2 μS by extending the ACKX width variable circuit 224 by 1 μS (step S408: FIG. 7 (see t9 to t10 in FIG. 7), by returning to step S405, the time T2 required for data transfer from the host computer 100 when the ACKX signal width is 2 μS is measured. Then, the process proceeds to step S406, where the data transfer required time T2 when the ACKX signal width is 2 μS and the transfer required time 10 times the data transfer required time T1 when 4 μS are compared. Thereafter, the same processing is performed until the host computer 100 recognizes the ACKX signal and can transmit the next data, and the optimum ACKX signal width is automatically determined.
[0053]
As described above, in the third embodiment, the ACKX signal width variable circuit 224 is made variable in the ACKX signal width even during data reception, and various ACKX signal widths are automatically set, and data transfer when these ACKX signal widths are set. The required time is measured by the transfer time measuring circuit 225, and the optimum ACKX signal width is searched and automatically determined based on the measurement result of the data transfer required time. Therefore, it is possible for the user to set the optimum ACKX signal width by operating the ACKX width setting mode key 232, to improve the data transfer speed, and to realize high-speed printing.
[0054]
The present invention is not limited to the above-described embodiments. For example, in the case of extending the ACKX signal width in the second and third embodiments, various methods such as extending 0.5 μS instead of 1 μS are available. Application deformation is possible.
[0055]
Further, in consideration of variation due to temperature change or the like, a margin of about 0.5 μS may be added to the measured ACKX width.
[0056]
【The invention's effect】
  As described above, according to the present invention, in a printing apparatus that has an interface unit that receives data transferred from a host computer, and performs printing by exchanging data with the host computer by a handshake method. ,First setting means for setting the ACKX signal width of the ACKX signal to be output when the data transferred from the host computer is received to the first ACKX signal width, and a printing state based on the transferred data is checked. If the printing state is good, the first ACKX signal width is set as is, and if the printing state is bad, the second ACKX is longer than the first ACKX signal width. A second setting means for setting the signal width;Thus, it is possible to perform printing at a higher data transfer speed while maintaining a good printing state. OrAn interface unit that receives data transferred from a host computer, and receives data transferred from the host computer in a printing apparatus that performs printing by exchanging data with the host computer by a handshake method First measuring means for measuring a first data transfer required time in the case of the first ACKX signal width set as the ACKX signal width of the ACKX signal to be output in the case, and a first shorter than the first ACKX signal width 2nd measuring means for measuring the second data transfer required time in the case of ACKX signal width of 2, the first data transfer required time measured by the first measuring means and the second measuring means As a result of comparing the measured second data transfer time, the host computer can recognize the ACKX signal. When waiting for the ACKX signal, the means for outputting the ACKX signal having the first ACKX signal width, the first data transfer required time measured by the first measuring means, and the second measuring means When the host computer is not able to recognize the ACKX signal and is waiting for the ACKX signal as a result of comparing with the second data transfer time measured by the above, the ACKX signal width of the ACKX signal is set to the second ACKX signal width. Since there is a third setting means for setting longer than the ACKX signal width,The data transfer speed from the host computer to the printer can be improved as much as possible according to the performance of the host computer and printer, and high-speed printing can be realized.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a schematic configuration of a data processing system using a printer according to an embodiment of the present invention.
FIG. 2 is a flowchart showing data transfer control unique to the first embodiment.
FIG. 3 is a flowchart showing data transfer control unique to the second embodiment.
FIG. 4 is a flowchart showing data transfer control unique to the third embodiment.
FIG. 5 is a time chart showing an ideal case when the present invention is applied.
FIG. 6 is a time chart showing a case where the present invention is applied to a host computer with low processing capability.
FIG. 7 is a time chart for explaining a case where the host computer cannot recognize the ACKX signal.
FIG. 8 is a time chart showing conventional data transfer control.
FIG. 9 is a time chart showing conventional data transfer control when the processing capability of the host computer and printer is improved.
[Explanation of symbols]
100: Host computer
113 ... RAM 113
120 ... interface section
121 ... transmission buffer
122... STBX generation circuit
123 ... BUSY / ACKX detection circuit
200: Printer 200
211 ... CPU
212 ... ROM
220 ... Interface section
221... Reception buffer 221
222 ... STBX detection circuit
223 ... BUSY / ACKX generation circuit
224... ACKX width variable circuit 224
225 ... Transfer time measurement circuit
230 ... Operation panel 230
231 ... ACKX width setting key
232 ... ACKX width setting mode key

Claims (10)

In a printing apparatus that has an interface unit for receiving data transferred from a host computer and performs printing by performing data transfer with the host computer by a handshake method,
First setting means for setting an ACKX signal width of an ACKX signal to be output when receiving data transferred from the host computer to a first ACKX signal width;
Means for checking the printing status based on the transferred data;
If the printing state is good, the first ACKX signal width is set as it is, and if the printing state is bad, the second ACKX signal width is longer than the first ACKX signal width. A second setting means for setting;
A printing apparatus comprising: The first setting means sets the first ACKX signal width according to the operation of the ACKX width setting key, and the second setting means sets the second ACKX signal width according to the operation of the ACKX width setting key. setting printing apparatus according to claim 1, characterized in that. In a printing apparatus that has an interface unit for receiving data transferred from a host computer and performs printing by exchanging data with the host computer by a handshake method,
  First measuring means for measuring a first data transfer required time in the case of a first ACKX signal width set as an ACKX signal width of an ACKX signal output when data transferred from the host computer is received; ,
  Second measuring means for measuring a second data transfer required time in the case of a second ACKX signal width shorter than the first ACKX signal width;
  The host computer recognizes the ACKX signal as a result of comparing the first data transfer required time measured by the first measuring means and the second data transfer required time measured by the second measuring means. Means for outputting an ACKX signal of the first ACKX signal width when waiting for the ACKX signal without being possible;
  The host computer recognizes the ACKX signal as a result of comparing the first data transfer required time measured by the first measuring means and the second data transfer required time measured by the second measuring means. And a third setting unit that sets an ACKX signal width of the ACKX signal to be longer than the second ACKX signal width when waiting for the ACKX signal. 4. The printing apparatus according to claim 3, wherein the first measuring unit or the second measuring unit measures a time required for data transfer by measuring a cycle of the STBX signal from the host computer. In a printing apparatus that has an interface unit for receiving data transferred from a host computer and performs printing by performing data transfer with the host computer by a handshake method,
First measuring means for measuring a first data transfer required time in the case of a first ACKX signal width set as an ACKX signal width of an ACKX signal output when data transferred from the host computer is received; ,
Second measuring means for measuring a second data transfer required time in the case of a second ACKX signal width shorter than the first ACKX signal width;
The first first data transfer required time measured by the measurement means, a result of a second data transfer required time measured by the second measuring means is compared, said second data after the transfer time required that if it is extremely long compared between the data transfer required when the first, the ACKX signal before Symbol first ACKX signal width temporarily output to be able to transfer the next data , the comparison result between the first data transfer time required in the previous SL second ACKX data transfer said a required time between first ACKX signal width when the signal width stepwise increase was ACKX signal width than And a determining unit that determines the ACKX signal width when the ACKX signal can be recognized. In a printing method having an interface unit for receiving data transferred from a host computer and performing printing by exchanging data with the host computer by a handshake method,
A first setting step of setting an ACKX signal width of an ACKX signal output when receiving data transferred from the host computer to a first ACKX signal width;
A step of checking the printing status based on the transferred data;
If the printing state is good, the first ACKX signal width is set as it is, and if the printing state is bad, the second ACKX signal width is longer than the first ACKX signal width. A second setting step to set;
A printing method characterized by comprising: The first setting step sets the first ACKX signal width according to the operation of the ACKX width setting key, and the second setting step sets the second ACKX signal width according to the operation of the ACKX width setting key. setting of the print according to claim 6, wherein that. In a printing method that has an interface unit for receiving data transferred from a host computer, and performs printing by exchanging data with the host computer by a handshake method,
  A first measuring step of measuring a first data transfer required time in the case of a first ACKX signal width set as an ACKX signal width of an ACKX signal output when data transferred from the host computer is received; ,
  A second measuring step of measuring a second data transfer required time in the case of a second ACKX signal width shorter than the first ACKX signal width;
  The host computer recognizes the ACKX signal as a result of comparing the first time required for data transfer measured in the first measuring step and the second time required for data transfer measured in the second measuring step. If not waiting for the ACKX signal, outputting an ACKX signal of the first ACKX signal width;
  The host computer recognizes the ACKX signal as a result of comparing the first time required for data transfer measured in the first measuring step and the second time required for data transfer measured in the second measuring step. And a setting step of setting an ACKX signal width of the ACKX signal longer than the second ACKX signal width when waiting for the ACKX signal. 9. The printing method according to claim 8, wherein in the first measuring step or the second measuring step, a data transfer time is measured by measuring a period of an STBX signal from the host computer. In a printing method having an interface unit for receiving data transferred from a host computer and performing printing by exchanging data with the host computer by a handshake method,
A first measuring step of measuring a first data transfer required time in the case of a first ACKX signal width set as an ACKX signal width of an ACKX signal output when data transferred from the host computer is received; ,
A second measuring step of measuring a second data transfer required time in the case of a second ACKX signal width shorter than the first ACKX signal width;
Said first measuring first data transfer required time measured in step, the second measuring step a second data transfer required time and the comparison result which is measured by, said second data after the transfer time required that if it is extremely long compared between the data transfer required when the first, the ACKX signal before Symbol first ACKX signal width temporarily output to be able to transfer the next data , the comparison result between the first data transfer time required in the previous SL second ACKX data transfer said a required time between first ACKX signal width when the signal width stepwise increase was ACKX signal width than And a confirming step for confirming the ACKX signal width when the ACKX signal can be recognized.

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