Information
-
Patent Grant
-
6519443
-
Patent Number
6,519,443
-
Date Filed
Tuesday, October 2, 200122 years ago
-
Date Issued
Tuesday, February 11, 200321 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
-
CPC
-
US Classifications
Field of Search
US
- 399 381
- 399 388
- 399 391
- 399 394
- 399 396
- 271 317
- 271 110
- 271 25801
-
International Classifications
-
Abstract
A method for calculating a print medium pick time for an imaging apparatus that transports media at variable speeds along a media path, includes the steps of providing a staging process for varying a transport velocity of a media sheet before transferring an image to the media sheet at the image transfer location, the staging process being used for positioning a top writing line margin of the media sheet in relation to the image at the image transfer location; determining a time period t1 corresponding to a time when a pick motor is started to pick the media sheet to a time when the staging process is started; determining a derived time period t2 representative of a normalized time from when the staging process is started to a time when a media path sensor senses the media sheet; and determining a compensated calculated pick time for the media sheet by summing the time period t1 with the time period t2.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to imaging systems, and, more particularly, to a method for calculating a print medium pick time for an imaging apparatus, such as an electrophotographic machine, that transports print media at variable speeds.
2. Description of the Related Art
In known electrophotographic machines, a sheet of paper is picked from an input device, such as a paper tray, prior to the start of the imaging process on a developing unit. As the paper moves through the paper path at a constant speed, the leading edge of the paper eventually actuates a paper path sensor which signals the machine to commence imaging onto the developing unit. The image is laid down on a single rotating photoconductive drum in the developing unit. Eventually, the image on the drum is transferred to a transfer medium and then onto a sheet of paper which contacts the transfer medium at a precise point in time in order to establish a desired top writing line margin. This process is repeated for each individual sheet of paper, allowing the machine the luxury of waiting until each page is at a known location in the paper path before beginning the imaging process. Since the paper is picked prior to imaging, thereby allowing the electrophotographic process to wait for the paper to arrive at a certain location before commencing imaging, the margin above the top writing line on the paper can be accurately controlled.
It may be desirable or necessary to design an electrophotographic machine such that imaging is begun on a developing unit before the sheet of paper is even picked from the input device. This requirement may be due to size limitations on the printer which reduce the maximum length of the paper path. It may also be due to the use of multiple developing units, each transferring an image of a respective color onto a same location on the transfer medium. That is, after an image is first scanned onto a photoconductive drum for a first color, the image is transferred onto an intermediate transfer medium belt. The belt then moves over to receive an image of a second color from a second photoconductive drum. The second image is received on top of and overlaps the first image. This process repeats for each of the photoconductive drums, and the completed composite image eventually reaches the paper transfer nip where it is transferred from the intermediate transfer medium belt onto the paper. Since additional time is required for transferring a separate image from each developing unit sequentially, it may be necessary to begin imaging on at least a first of the developing units before the paper is picked from the input device.
A variable sheet transfer velocity profile is used in order to allow a sheet of print medium picked from a given media source tray to arrive at the image transfer location at the proper time and at the proper velocity to accommodate an accurate location of the top margin of the image to the sheet. Such a use of a variable sheet transfer velocity profile, however, complicates the task of picking a sheet of print medium from a given tray at an appropriate time.
What is needed in the art is a method for calculating a print medium pick time for an imaging apparatus, such as an electrophotographic machine, that transports print media at variable speeds.
SUMMARY OF THE INVENTION
The present invention provides a method for calculating a print medium pick time for an imaging apparatus, such as an electrophotographic machine, that transports print media at variable speeds.
The invention comprises, in one form thereof, a method for calculating a print medium pick time for an imaging apparatus that transports media at variable speeds along a media path. The method includes the steps of providing a media path sensor for sensing an arrival of a media sheet at a known location along the media path; providing an image on an image transfer member; providing an image transfer location adjacent the media path; providing a staging process for varying a transport velocity of the media sheet before transferring the image to the media sheet at the image transfer location, the staging process being used for positioning a top writing line margin of the media sheet in relation to the image at the image transfer location; determining a time period t
1
corresponding to a time when a pick motor is started to pick the media sheet to a time when the staging process is started; determining a derived time period t
2
representative of a normalized time from when the staging process is started to a time when the media path sensor senses the media sheet; and determining a compensated calculated pick time for the media sheet by summing the time period t
1
with the time period t
2
.
In another form thereof, the invention comprises a printer. The printer includes a media tray for holding media sheets. A pick motor is provided for picking a media sheet from the media tray. A staging system is provided and includes a staging motor operating in accordance with a staging process effecting a staging algorithm for transporting the media sheet along a media path. A staging motor encoder is coupled to the staging system for determining a distance traveled by the media sheet. A sensor is provided for sensing an arrival of the media sheet at a known location along the media path. A microcontroller is provided for executing computer instructions to determine a compensated calculated pick time (CPTcom
x
) for the media sheet, the computer instructions effecting the equation:
CPTcom
x
=Staging_Encoders_From_Staging_Algorithm_Start_To_S
2
_Make/Staging_Encoders_Per_Second_At_Normal_Process Speed+Staging_Start_TimeStamp_Pick_Start_TimeStamp
wherein:
Staging_Encoders_From_Staging_Algorithm_Start_To_S
2
_Make is a number of staging motor encoder pulses counted from when the staging algorithm starts until the sensor detects the media sheet;
Staging_Encoders_Per_Second_At_Normal_Process_Speed is set to a number of encoder pulses per second that should occur if the staging motor was rotating at a known process speed;
Staging
13
Start
13
TimeStamp is a system time of the printer when the staging algorithm is started; and
Pick_Start_TimeStamp is a system time of the printer when the pick motor is started.
An advantage of the present invention is that an accurate pick time can be established for a media sheet in an imaging system that transports print media sheets at variable speeds.
Another advantage of the present invention is that it minimizes the need to make extreme staging changes in positioning a media sheet in relation to an image.
Still another advantage is that the present invention can be implemented using existing hardware within the imaging apparatus.
BRIEF DESCRIPTION OF THE DRAWINGS
The above-mentioned and other features and advantages of this invention, and the manner of attaining them, will become more apparent and the invention will be better understood by reference to the following description of an embodiment of the invention taken in conjunction with the accompanying drawing, wherein:
FIG. 1
is a partial, schematic, side view of one embodiment of a laser printer in which the method of the present invention may be used.
The exemplification set out herein illustrates one preferred embodiment of the invention, in one form, and such exemplification is not to be construed as limiting the scope of the invention in any manner.
DETAILED DESCRIPTION OF THE INVENTION
In
FIG. 1
there is shown one embodiment of a multicolor laser printer
10
including toner cartridges
12
,
14
,
16
,
18
, photoconductive drums
20
,
22
,
24
,
26
, a drum motor
28
, an intermediate transfer member belt
30
, a belt motor
32
, an input media tray
34
, an input media tray
35
, a staging motor
36
, media path sensors S
1
and S
2
, and a microcontroller
38
.
Each of four laser print heads (not shown) scans a respective laser beam in a scan direction, perpendicular to the plane of
FIG. 1
, across a respective one of photoconductive drums
20
,
22
,
24
and
26
. Each of photoconductive drums
20
,
22
,
24
and
26
is negatively charged to approximately −900 volts and is subsequently discharged to a level of approximately −200 volts in the areas of its peripheral surface that are impinged by a respective one of the laser beams. During each scan of a laser beam across a photoconductive drum, each of photoconductive drums
20
,
22
,
24
and
26
is continuously rotated, clockwise in the embodiment shown, in a process or “cross-scan” direction indicated by direction arrow
40
. The scanning of the laser beams across the peripheral surfaces of the photoconductive drums is cyclically repeated, thereby discharging the areas of the peripheral surfaces on which the laser beams impinge.
The toner in each of toner cartridges
12
,
14
,
16
and
18
is of a separate, respective color, such as cyan, magenta, yellow and black. Thus, each of the four laser print heads controls printing in a respective color, such as cyan, magenta, yellow or black. Further, the toner in each of toner cartridges
12
,
14
,
16
and
18
is negatively charged to approximately −600 volts. Thus, when the toner from cartridges
12
,
14
,
16
and
18
is brought into contact with a respective one of photoconductive drums
20
,
22
,
24
and
26
, the toner is attracted to and adheres to the portions of the peripheral surfaces of the drums that have been discharged to −200 volts by the laser beams. As belt
30
rotates in the direction indicated by arrow
42
, the toner from each of drums
20
,
22
,
24
and
26
is transferred to the outside surface of belt
30
in a respective drum transfer nip
44
. The direction indicated by arrow
42
is also known as the process direction of belt
30
. As a print medium, such as paper
46
, travels along a media path
48
in the direction indicated by arrow
49
, the toner is transferred from belt
30
to the surface of the paper
46
in an image transfer nip
50
between opposing rollers
52
and
54
. Image transfer nip
50
is also know as a“toner transfer nip”, and defines an image transfer location.
Imaging may begin, for example, at least on first photoconductive drum
20
, before a first sheet of paper
46
is picked from one of input media trays
34
,
35
. The image begins to be transferred onto transfer belt
30
, and when the image on belt
30
reaches a point that is a certain distance away from image transfer nip
50
, one of input media trays
34
,
35
receives a pick command from microcontroller
38
.
Microcontroller
38
includes, for example, a microprocessor, random access memory (RAM), read only memory (ROM) and an input/output (I/O) interface.
Microcontroller
38
determines when the electrophotographic system begins to image on at least one of photoconductive drums
20
,
22
,
24
and
26
. Microcontroller
38
tracks the first line position on photoconductive drum
20
, if color, or on photoconductive drum
26
, if monochrome, and the first line position on transfer belt
30
, using feedback from the black laser print head associated with photoconductive drum
26
. It is to be understood that the color print heads associated with color photoconductive drums
20
,
22
and
24
are synchronized with respect to the black print head. Drum motor
28
drives photoconductive drum
20
. Drum motor
28
may or may not also drive drums
22
,
24
and
26
.
Microcontroller
38
provides a velocity command to belt motor
32
, and belt motor
32
responds by achieving the commanded velocity. As a result, an assumed velocity of transfer belt
30
is achieved, and accordingly, a location of an image formed on transfer belt
30
is known based on the assumed velocity.
At some designated time, a designated one of input media trays
34
,
35
receives a command from microcontroller
38
to pick a sheet of print media, such as paper. The sheet of paper moves through media path
48
at a constant speed and eventually actuates a paper path sensor S
1
. Microcontroller
38
immediately begins tracking incrementally the position of the paper by monitoring the feedback of a staging motor encoder
60
, this one being associated with staging motor
36
. From the tracked distance traveled by the sheet of paper after tripping paper path sensor S
1
, and the known distance between S
1
and image transfer nip
50
, the distance remaining for the sheet of paper to travel before reaching image transfer nip
50
can be calculated.
The inter-sheet gap is small in comparison to the media path length and the image path length. Thus, no adjustment to media position can begin until the preceding sheet has been completely cleared from media path
48
. This is determined by monitoring another media path sensor S
2
. By monitoring when the trailing edge of the preceding sheet has cleared sensor S
2
, microcontroller
38
can determine when the preceding sheet has exited the last driven rolls of motor
36
, thereby allowing the correction of the position error of the current sheet to begin, which is referred to herein as a staging process.
From the two calculated distances, i.e., from the image on belt
30
to image transfer nip
50
and from the current sheet of paper to image transfer nip
50
, microcontroller
38
calculates a correction needed to remove position error of the paper relative to its image so as to enable the paper to arrive at image transfer nip
50
at the time and speed required to produce an accurate top writing line margin with acceptable tolerance. The correction is accomplished by incrementally adjusting the linear speed of the media through media path
48
by incrementally changing the velocity of staging motor
36
. The speed of staging motor
36
is increased or decreased depending upon whether the current sheet of paper is behind or ahead of a desired, target position.
Microcontroller
38
generates a fixed time interrupt every 1 millisecond (ms), at which time the error in the relationship between the image position and the paper position is determined. This position error is multiplied by a gain factor in a control equation that produces a new desired velocity for staging motor
36
. If the error is zero, the velocity of staging motor
36
is not changed from the nominal. If the sheet of paper is ahead of or behind the desired position, a new paper path motor speed that would reduce the error for that sampling point is calculated by a staging algorithm of the staging process as implemented by microcontroller
38
. As the position error decreases, the amount of velocity change also decreases to the point that zero error produces the nominal velocity. The new, changed speed of staging motor
36
is limited by minimum and maximum values in order to allow for reasonable power requirements, acceptable acoustics, and a stable control system. This also bounds the amount of error that can be removed.
The new desired speed is then fed into a motor speed control algorithm, i.e., staging algorithm, executed within microcontroller
38
. Feedback from staging motor encoder
60
is used to maintain the speed of staging motor
36
at the new desired speed, which may be unchanged if the sheet of paper is already“on schedule”, i.e., at a proper point along media path
48
in order to arrive at image transfer nip
50
at the desired point in time and at the desired speed. A signal from encoder
60
is used as another interrupt into microcontroller
38
. Again, the timing of the interrupt is chosen such that minimum bandwidth is required, e.g., approximately 1 ms between interrupts. The control code within microcontroller
38
sets the gain, encoder divide-by values (which sets interrupt timing), and other control parameters based upon the newly requested speed from the error correction routine. Each time microcontroller
38
receives this interrupt, microcontroller
38
uses the parameters to adjust the voltage applied to staging motor
36
in order to maintain the desired speed.
The desired speed of staging motor
36
is updated by microcontroller
38
at each 1 ms timer interrupt. These updates continue until the remaining time until the sheet of paper reaches image transfer nip
50
is approximately 100 ms. At this time, the speed of the sheet of paper is set to normal process speed, for example 110 millimeters per second (mm/s) at 20 pages per minute (ppm), and is held constant, and the image is transferred onto the sheet of paper with a correct top writing line margin that is within the acceptable tolerance.
If the top writing line margin is not within the acceptable tolerance, it is possible that the error has been introduced by variances in the predetermined number of motor revolutions required to transport the paper from sensor S
1
to image transfer nip
50
, and/or the predetermined number of motor revolutions required for the image to travel between photoconductive drum
20
and image transfer nip
50
. This new error is repeatable, and can be eliminated by allowing these values to be“tweaked” and stored in a nonvolatile memory
62
connected to microcontroller
38
. For example, if a test print page shows that the top margin is out of specifications, then an operator can use a software utility to adjust the stored values that microcontroller
38
uses to calculate position errors. These stored values represent the distance between paper sensor S
1
and image transfer nip
50
, and/or the length of transfer belt
30
between photoconductive drum
20
and image transfer nip
50
. By adjusting the stored values, the image can be moved up or down on the page by the adjusted amount. These values are stored and used for any and all future print pages. Thus, the adverse effects of the manufacturing tolerances of media path
48
and transfer belt
30
can be eliminated.
Multiple feedback loops are used such that paper position errors introduced into the paper path can be effectively reduced in order to provide an accurate top writing line margin, and to allow the paper to be“handed-off” at an optimal speed into image transfer nip
50
. Feedback from paper path sensors S
1
and/or S
2
and the signals from staging motor encoder
60
are used to determine and track paper position. Position error can then be calculated between paper and image. The speed of staging motor
36
is adjusted by microcontroller
38
to effectively remove the position error such that the paper arrives at image transfer nip
50
coincident with the image and at the desired speed. The speed of staging motor
36
is carefully controlled to provide acceptable power levels, acoustics and stability.
In order to minimize the initial top margin error, an accurate estimated pick time for each sheet of print media is needed. As shown in
FIG. 1
, associated with input media tray
34
is a pick roller assembly
70
, including a pick motor
72
. Also, associated with input media tray
35
is a pick roller assembly
74
, including a pick motor
76
. The estimated pick time is the length of time that microcontroller
38
estimates it will take from starting one of pick motors
72
,
76
to when the sheet of print media reaches a known point, such as for example the location of paper path sensor S
2
.
If calculated pick times for sheets picked from the same source, such as input media tray
34
, are available, the calculated pick times are used to formulate the estimated pick time for the current sheet located in media tray
34
. Microcontroller
38
executes computer instructions for calculating the estimated pick time of the current sheet based on weighted multiple prior calculated pick times, wherein the highest weight is applied to the most recent prior calculated pick time so as to have the most impact on the outcome of the calculation for the estimated pick time of the current, i.e., next, sheet. For example, microcontroller
38
includes computer instructions for performing the mathematical equation:
EPT=CPT
1
/2+CPT
2
/4+CPT
3
/4
wherein:
EPT is the estimated pick time for the next sheet to be picked;
CPT
1
is the calculated pick time for the immediately previous media sheet;
CPT
2
is the calculated pick time for the second previous media sheet; and
CPT
3
is the calculated pick time for the third previous media sheet.
As used herein, the estimated pick time (EPT) is the estimated length of time it will take to pick media from a particular source tray, such as one of input trays
34
and
35
. The calculated pick time (CPT
x
, wherein x is 1, 2 or 3) is the calculated length of time from when a pick motor, such as one of pick motors
72
,
76
, is started to when media path sensor S
2
was made. Media path sensor S
2
is“made” when media path sensor S
2
senses a media sheet.
Of course, if the velocity of the transported media sheets remained constant, microcontroller
38
can arrive at calculated pick time by executing computer instructions to effect the following equation:
CPT
x
=S
2
13
Made_TimeStamp−Pick_Start_TimeStamp
wherein:
CPT
x
is the calculated pick time for a previous sheet,
S
2
_Made_TimeStamp is the system time of printer
10
when media path sensor S
2
is made, and
Pick_Start_TimeStamp is the system time of printer
10
when one of pick motors
72
,
76
is started.
However, as described above, the staging algorithm of the staging process controls the velocity of the transport of the media sheet in an attempt to minimize the top margin error. Thus, using the equation, CPT
x
=S
2
_Made_TimeStamp−Pick_Start_TimeStamp, for determining the values for arriving at values for each of calculated pick times CPT
1
, CPT
2
and CPT
3
would introduce errors in the calculated pick time due to variations in the velocity of the transport of the media sheet.
For example, if a sheet of media reaches paper path sensor S
1
early, i.e., the media is ahead of the image and would arrive early at the image transfer location of image transfer nip
50
, the staging algorithm slows the media down before the media path sensor S
2
is made, i.e., when media path sensor S
2
senses a media sheet. Assuming a process speed of
20
pages per minute, the media traveling at 109.8 millimeters per second (mm/s) prior to executing the staging algorithm and slowing the media to 54.7 mm/s for 8 mm before media path sensor S
2
is made, then the equation, CPT
x
=S
2
_Made _TimeStamp−Pick_Start_TimeStamp, would result in a 73.4 milliseconds (ms) error in the calculated pick time, which would translate to a top margin error of about 8.1 mm.
As a further example, once the image reaches a distance away from the image transfer location of image transfer nip
50
that is equal to the distance from media path sensor S
2
to image transfer nip
50
, and if media path sensor S
2
has not been made, then it is known that the media is late in relation to the location of the image to be transferred. In this case where the media sheet reaches media path sensor S
2
late, i.e., the media sheet is behind the image and would arrive at the image transfer location late, the staging process increases the media sheet speed before the media sheet reaches paper path sensor S
2
. Assuming a process speed of 10 pages per minute, the media is traveling at 54.7 mm/s prior to executing the staging algorithm and the media is 25.4 mm behind the image, then the equation, CPT
x
=S
2
13
Made_TimeStamp−Pick_Start_TimeStamp, would result in 230 ms error in the calculated pick time, which would translate to 12.7 mm of top margin error.
Thus, if the staging algorithm of the staging process does modify the media sheet process speed before media path sensor S
2
is made, then the calculated pick time needs to be compensated to reduce the error in arriving at a calculated pick time, and in turn, to reduce the error in arriving at the estimated pick time for the next media sheet to be picked, so as to reduce the initial top margin error. In such an event, microcontroller
38
includes computer instructions that are executed to effect the following equation to arrive at a compensated calculated pick time (CPTcom
x
). The following equation performs the compensation by converting the distance over which the staging algorithm of the staging process was operating into a length of time by dividing it by the known normal process speed:
CPTcom
x
=Staging
13
Encoders_From_Staging_Algorithm_Start_To_S
2
_Make/Staging_Encoders_Per_Second_At_Normal_Process_Speed+Staging_Start_TimeStamp−Pick_Start_TimeStamp
wherein:
CPTcom
x
is the compensated calculated length of time from a pick motor start to when media path sensor S
2
is made for a previous sheet;
Staging_Encoders_From_Staging_Algorithm_Start_To_S
2
_Make is the number of staging motor encoder pulses counted from when the staging algorithm of the staging process starts until media path sensor S
2
is made (i.e., a distance);
Staging_Encoders_Per_Second_At_Normal_Process_Speed is set to the number of encoder pulses per second that should occur if the staging motor was rotating at its current normal (no error correction) process speed;
Staging
13
Start
13
TimeStamp is the system time of printer
10
when the staging algorithm is started, since the staging motor may no longer match normal process speed; and
Pick_Start_TimeStamp is the system time of printer
10
when the pick motor is started.
In the CPTcom
x
equation, it should be noted that two time periods are taken into account. First, the difference term“Staging_Start_TimeStamp−Pick_Start_TimeStamp” provides a time period t
1
corresponding to the time at which the pick motor started to the time when the staging process started. Second, the quotient term“Staging
13
Encoders
13
From_Staging
13
Algorithm
13
Start_To_S
2
_Make/Staging
13
Encoders
13
Per_Second_At_Normal_Process
13
Speed” provides a time derived period t
2
representative of a normalized time from when the staging process started to the time when media path sensor S
2
was made. Thus, the compensated calculated pick time is the sum of time periods t
1
and t
2
.
In a preferred embodiment of the present invention, the equation for calculating CPTcom
x
is used in arriving at values for each of individual calculated pick times CPT
1
, CPT
2
and CPT
3
used in calculating estimated pick time EPT. Also, the preferred embodiment uses the individual calculated pick times of three consecutive prior media sheets in calculating estimated pick time EPT. Those skilled in the art will recognize, however, that equations CPTcom
x
and EPT may be modified and adapted to accommodate the use of any number or combination of one or more prior calculated pick times in determining an estimated pick time for a next media sheet without departing from the spirit and scope of the present invention.
For printer
10
, the estimated pick time EPT is used to determine whether to pick first, or whether to image first. In printer
10
, the location of the image on intermediate transfer medium belt
30
and the rate of rotation of intermediate transfer medium belt
30
are known. As such, it is further known the length of time that it will take for the image to reach the image transfer location at image transfer nip
50
. Also, the velocity of a media sheet following the making of, i.e., sensing by, media path sensor S
2
is known, and the time that it takes for the media sheet to travel from media path sensor S
2
to reach the image transfer location at image transfer nip
50
is determined based on a normal process speed, i.e., nominal process velocity.
As an example of use of the estimated pick time EPT, assume it is known that the length of time that it will take for the image to reach the image transfer location at image transfer nip
50
is 3.0 seconds, and it is known that the time that it takes for the media sheet to travel from media path sensor S
2
to reach the image transfer location at image transfer nip
50
is 0.5 seconds. Now, if the estimated pick time is 1.75 seconds, then it is necessary to begin imaging first, before picking, and to delay picking for 0.75 seconds, so that the image and the media sheet reach the image transfer location at image transfer nip
50
simultaneously. In contrast, if the estimated pick time is 2.75 seconds, then it is necessary to pick first, before imaging, and to delay imaging for 0.25 seconds, so that the image and the media sheet reach the image transfer location at image transfer nip
50
simultaneously.
While this invention has been described as having a preferred design, the present invention can be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this invention pertains and which fall within the limits of the appended claims.
Claims
- 1. A method for calculating a print medium pick time for an imaging apparatus that transports media at variable speeds along a media path, comprising the steps of:providing a media path sensor for sensing an arrival of a media sheet at a known location along said media path; providing an image on an image transfer member; providing an image transfer location adjacent said media path; providing a staging process for varying a transport velocity of said media sheet before transferring said image to said media sheet at said image transfer location, said staging process being used for positioning a top writing line margin of said media sheet in relation to said image at said image transfer location; determining a time period t1 corresponding to a time when a pick motor is started to pick said media sheet to a time when said staging process is started; determining a derived time period t2 representative of a normalized time from when said staging process is started to a time when said media path sensor senses said media sheet; and determining a compensated calculated pick time for said media sheet by summing said time period t1 with said time period t2.
- 2. The method of claim 1, wherein said time period t2 is derived based on a quotient “Staging13 Encoders13 From13 Staging13 Algorithm_Start_To_S2_Make/Staging13 Encoders13 Per_Second_At_Normal_Process13 Speed”,wherein: “Staging13 Encoders13 From_Staging13 Algorithm13 Start_To_S2_Make” is a number of staging motor encoder pulses counted from when said staging process starts until said media path sensor detects said media sheet; and “Staging13 Encoders13 Per_Second_At_Normal13 Process13 Speed” is set to a number of encoder pulses per second that should occur if a staging motor was rotating at a known normal process speed.
- 3. The method of claim 1, wherein each of the determining steps are repeated for each of a plurality of media sheets to determine an individual compensated calculated pick time for each of said plurality of media sheets.
- 4. The method of claim 3, further comprising the step of determining an estimated pick time (EPT) of a next media sheet based on a weighted average of said individual compensated calculated pick time for said each of said plurality of media sheets.
- 5. The method of claim 4, wherein said weighted average assigns a higher weight to an immediately previous one of said plurality of media sheets.
- 6. The method of claim 4, wherein said estimated pick time (EPT) is based on the formula:EPT=CPT1/2+CPT2/4+CPT3/4 wherein: CPT1 is a calculated pick time for an immediately previous media sheet, CPT2 is a calculated pick time for a second previous media sheet, and CPT3 is a calculated pick time for a third previous media sheet.
- 7. The method of claim 1, wherein each of the determining steps are performed for each of three consecutive media sheets to determine an individual compensated calculated pick time for each of said three consecutive media sheets.
- 8. The method of claim 7, further comprising the step of determining an estimated pick time (EPT) of a next media sheet based on a weighted average of said individual compensated calculated pick time for each of said three consecutive media sheets.
- 9. The method of claim 8, wherein said estimated pick time (EPT) is based on the formula:EPT=CPT1/2+CPT2/4+CPT3/4 wherein: CPT1 is a calculated pick time for an immediately previous media sheet, CPT2 is a calculated pick time for a second previous media sheet, and CPT3 is a calculated pick time for a third previous media sheet.
- 10. The method of claim 1, wherein each of the determining steps is performed by a microcontroller executing computer instructions.
- 11. A system for calculating a print medium pick time for an imaging apparatus that transports media at variable speeds along a media path, comprising:a media path sensor for sensing an arrival of a media sheet at a known location along said media path; an image transfer member for receiving an image; an image transfer nip defining an image transfer location adjacent said media path; staging means for executing a staging process for varying a transport velocity of said media sheet before transferring said image to said media sheet at said image transfer location, said staging process positioning a top writing line margin of said media sheet in relation to said image at said image transfer location; means for determining a time period t1 corresponding to a time when a pick motor is started to pick said media sheet to a time when said staging process is started; means for determining a derived time period t2 representative of a normalized time from when said staging process is started to a time when said media path sensor senses said media sheet; and means for summing said time period t1 with said time period t2 to determine a compensated calculated pick time for said media sheet.
- 12. The system of claim 11, wherein said time period t2 is derived based on a quotient “Staging13 Encoders13 From13 Staging13 Algorithm_Start_To_S2_Make/Staging13 Encoders13 Per_Second_At_Normal_Process_Speed”,wherein: “Staging13 Encoders13 From13 Staging13 Algorithm_Start_To_S2_Make” is a number of staging motor encoder pulses counted from when said staging process starts until said media path sensor detects said media sheet; and “Staging13 Encoders13 Per_Second_At_Normal_Process_Speed” is set to a number of encoder pulses per second that should occur if a staging motor was rotating at a known normal process speed.
- 13. The system of claim 11, wherein said means for determining said time period t1, said means for determining said derived time period t2 and said means for summing determine an individual compensated calculated pick time for each of a plurality of media sheets.
- 14. The system of claim 13, further comprising means for determining an estimated pick time (EPT) of a next media sheet based on a weighted average of said individual compensated calculated pick time for said each of said plurality of media sheets.
- 15. The system of claim 14, wherein said weighted average assigns a higher weight to an immediately previous one of said plurality of media sheets.
- 16. The system of claim 14, wherein said estimated pick time (EPT) is based on the formula:EPT=CPT1/2+CPT2/4+CPT3/4 wherein: CPT1 is a calculated pick time for an immediately previous media sheet, CPT2 is a calculated pick time for a second previous media sheet, and CPT3 is a calculated pick time for a third previous media sheet.
- 17. The system of claim 11, wherein each of said means for determining said time period t1, said means for determining said derived time period t2 and said means for summing determine an individual compensated calculated pick time for each of three consecutive media sheets.
- 18. The system of claim 17, further comprising means for determining an estimated pick time (EPT) of a next media sheet based on a weighted average of said individual compensated calculated pick time for each of said three consecutive media sheets.
- 19. The system of claim 18, wherein said estimated pick time (EPT) is based on the formula:EPT=CPT1/2+CPT2/4+CPT3/4 wherein: CPT1 is a calculated pick time for an immediately previous media sheet, CPT2 is a calculated pick time for a second previous media sheet, and CPT3 is a calculated pick time for a third previous media sheet.
- 20. The system of claim 11, wherein each of said means for determining and said means for summing is a microcontroller that executes computer instructions.
- 21. A printer, comprising:a media tray for holding media sheets; a pick motor for picking a media sheet from said media tray; a staging system including a staging motor operating in accordance with a staging process effecting a staging algorithm for transporting said media sheet along a media path; a staging motor encoder coupled to said staging system for determining a distance traveled by said media sheet; a sensor for sensing an arrival of said media sheet at a known location along said media path; and a microcontroller for executing computer instructions to determine a compensated calculated pick time (CPTcomx) for said media sheet, said computer instructions effecting the equation: CPTcomx=Staging13 Encoders13 From13 Staging13 Algorithm_Start_To_S2_Make/Staging13 Encoders13 Per_Second_At_Normal_Process13 Speed+Staging13 Start13 TimeStamp−Pick_Start_TimeStamp wherein: Staging13 Encoders13 From_Staging13 Algorithm13 Start_To_S2_Make is a number of staging motor encoder pulses counted from when said staging algorithm starts until said sensor detects said media sheet; Staging13 Encoders13 Per_Second_At_Normal_Process13 Speed is set to a number of encoder pulses per second that should occur if said staging motor was rotating at a known process speed; Staging13 Start13 TimeStamp is a system time of said printer when said staging algorithm is started; and Pick_Start_TimeStamp is a system time of said printer when said pick motor is started.
- 22. The printer of claim 21, wherein said microcontroller determines an individual compensated calculated pick time (CPTcomx) for each of a plurality of media sheets.
- 23. The printer of claim 22, wherein said microcontroller determines an estimated pick time (EPT) of a next media sheet based on a weighted average of said individual compensated calculated pick time (CPTcomx)for said each of said plurality of media sheets.
- 24. The printer of claim 23, wherein said weighted average assigns a higher weight to an immediately previous one of said plurality of media sheets.
- 25. The printer of claim 22, wherein said plurality of media sheets is three prior consecutive media sheets.
- 26. The printer of claim 22, wherein said microcontroller determines an estimated pick time (EPT) of a next media sheet based on the formula:EPT=CPT1/2+CPT2/4+CPT3/4 wherein: CPT1 is a calculated pick time for an immediately previous media sheet, CPT2 is a calculated pick time for a second previous sheet media, and CPT3 is a calculated pick time for a third previous media sheet.
US Referenced Citations (30)