Printing devices are widely used and may include a printhead enabling formation of text or images on a print medium. Such a printhead may be included in a printer cartridge that includes channels that carry ink to firing chambers. For instance, ink may be ejected onto the print medium by being fired through a firing chamber from an ink supply.
A printer can use a printer cartridge (e.g., an inkjet printer cartridge) to dispense ink. A printer cartridge can include a nozzle member including nozzles (e.g., nozzle orifices). The nozzles can release and/or eject ink using firing chambers. The location of a nozzle can be an address. An address can be a location of a nozzle in a primitive and/or on a nozzle member in general. A number of addresses can be grouped into a primitive. A primitive can be a particular number of addresses (e.g., six addresses) to eject ink. The firing chambers can be associated with an address and eject ink. The firing chambers can be fired in a particular order. As the firing of each firing chamber increases, a reduction in addresses per primitive can occur. For example, eight addresses per primitive can operate at a lower frequency (e.g., fluidic frequency below 48 KHz and electrical frequency below 96 KHz) than six addresses per primitive (e.g., fluidic frequency of 48 KHz and electrical frequency at 96 KHz). Lowering a number of addresses per primitive can cause cross-talk. Cross-talk can include neighboring nozzles firing close together. Firing neighboring nozzles can cause puddling when ink is fired from firing chambers that are too close together.
Cross-talk and electrical frequency can be related. As electrical frequency increases, a number of address per primitive may decrease. As the number of primitives decreases, cross-talk can increase. Interdigitating the addresses of a number of primitives (e.g., two primitives) can reduce cross-talk. Interdigitation can include interlocking two primitives. For example, non-interdigitated primitives can include an ordered series of nozzles identified as a first address (A1) of a first primitive (P1) (e.g., P1-A1), and subsequent address of the first primitive: P1-A2, P1-A3, P1-A4, P1-A5, P1-A6, and a first address of a second primitive (e.g., P2-A1), and subsequent addresses of the second primitive: P2-A2, P2-A3, P2-A4, P2-A5, and P2-A6. Interdigitated primitives can include an ordered series of nozzles identified as P1-A1, P2-A1, P1-A2, P2-A2, P1-A3, P2-A3, P1-A4, P2-A4, P1-A5, P2-A5, P1-A6, and P2-A6 (as illustrated in
The number of nozzles 119 can each be designated by an address. A set of addresses can make up a primitive. For example, a primitive can include six addresses that each designate a nozzle location. A nozzle member 117 can include a number of primitives (as illustrated in
A number of firing chambers can be associated with the number of nozzles P1-A1231-1 through P(n−1)-A6231-N and P2-A1233-1 through P(n)-A6233-N. The number of firing chambers can include a firing chamber associated with a first address of a first primitive (e.g., associated with nozzle P1-A1231-1). The number of firing chambers can include a first set of firing chambers associated with one primitive of each of the interdigitated sets of primitives. For example, the first set of firing chambers can be associated with nozzles 231-1 through 231-6. The first set of firing chambers can be associated with a first address of the one primitive of each of the interdigitated sets of primitives. For example, P1 can include A1 (e.g., nozzle P1-A1231-1) and is one primitive of the interdigitated set of P1 and P2 and includes the first address. Nozzle P3-A1231-7 can be associated with the first set of firing chambers as it includes a first address of P3 and P3 is one primitive of an interdigitated set of primitives (e.g., P3 and P4).
The number of firing chambers can include a second set of firing chambers associated with a first address of another or a different primitive of each of the interdigitated sets of primitives. For example, nozzle P2-A1233-1 includes a first address of the other primitive of the interdigitated set of primitive P1 and P2. Nozzle P4-A1233-7 can be associated with a firing chamber of the second set of firing chambers as nozzle P4-A1233-7 includes a first address of another or a different primitive of an interdigitated set (e.g., interdigitated set P3 and P4).
The first set of firing chambers associated with a first address of one primitive of each of the interdigitated sets of primitives can be fired before the second set of firing chambers associated with a first address of the other primitive of each of the interdigitated sets of primitives is fired. For example, a firing order can include nozzle P1-A1231-1, nozzle P3-A1231-7, nozzle P2-A1233-1, and nozzle P4-A1233-7.
The number of firing chambers can include a third set of firing chambers associated with a second address of the one primitive of each of the interdigitated sets of primitives. For example, the third set of firing chambers can be associated with nozzles P1-A2231-2 and P3-A2231-8 as both nozzles P1-A2231-2 and P3-A2231-8 include a second address and are of a first primitive of an interdigitated set of primitives (e.g., interdigitated set P1 and P2, and interdigitated set P3 and P4). The number of firing chambers can include a fourth set of firing chambers associated with a second address of the other primitive of each of the interdigitated sets of primitives. For example, the fourth set of firing chambers can be associated with nozzles P2-A2233-2 and P4-A2233-8. The third set of firing chambers associated with the second address of the one primitive of each of the interdigitated sets of primitives can be fired before a fourth set of firing chambers associated with a second address of the other primitive of each of the interdigitated sets of primitives. For example, a firing order can include firing a firing chamber associated with nozzle P1-A1231-1, nozzle P3-A1231-7, nozzle P2-A1233-1, nozzle P4-A1233-7, nozzle P1-A2231-2, nozzle P3-A2231-8, nozzle P2-A2233-2, and nozzle P4-A2233-8.
While in this example four primitives are described, examples are not so limited. The number of primitives can be more and/or fewer than four primitives. Each primitive can be designated with a number. The designated number can be based on an order of firing for each primitive. For example, a first primitive can include an address fired before a second primitive. A first odd number primitive can be interdigitated with a first even number primitive. Each subsequently numbered primitive can be interdigitated with each corresponding odd and even primitive. For example, a fifth and a sixth primitive can be interdigitated, etc.
A nozzle member 217 can include an array of ink nozzles (e.g., nozzles orifices) arranged in a number of primitives. The number of primitives can include a first primitive of the number of primitives interdigitated with a second primitive. The first and second primitive can be interdigitated so that a first address of the first primitive (e.g., nozzle P1-A1231-1) is in a first-ordered nozzle position and a first address of the second primitive (e.g., nozzle P2-A1233-1) is in a second-ordered nozzle position. An ordered nozzle position can include a position in a column of a nozzle member. For example, nozzle P1-A1231-1 is in a first position in the column in
The number of primitives can include a second primitive that includes a third, fourth, fifth, and sixth address in corresponding sixth (e.g., nozzle P2-A3233-3), eighth (e.g., nozzle P2-A4233-4), tenth (e.g., nozzle P2-A5233-5), and twelfth-ordered (e.g., nozzle P2-A6233-6) nozzle positions. The nozzle member 217 can include a third primitive of the number of primitives interdigitated with a fourth primitive. The third and fourth primitive can be interdigitated so that a first address of the third primitive is in a thirteenth-ordered nozzle position (e.g., nozzle P3-A1231-7) and a first address of the fourth primitive is in a fourteenth-ordered nozzle position (e.g., nozzle P4-A1233-7). The third and fourth primitive can be interdigitated so that a second address of the third primitive is in a fifteenth-ordered nozzle position (e.g., nozzle P3-A2231-8) and a second address of the fourth primitive is in a sixteenth-ordered nozzle position (e.g., nozzle P4-A2233-8). The third and fourth primitive can be interdigitated so that a third address is in a corresponding seventeenth-ordered nozzle position (e.g., nozzle P3-A3231-9). The third and fourth primitive can be interdigitated so that the fourth primitive includes a third address in a corresponding eighteenth-ordered nozzle position (e.g., nozzle P4-A3233-9).
A delay in firing of the number of firing chambers can include a dual propagation delay. For example, the following chart below can indicate a delay for firing of each firing chamber associated with the nozzles. The delay can be an analog delay. The delay can be in digital master clock increments (“MCLK”).
The value of n in the chart can be equal to the number of primitives in a column. For example, consider a column with four primitives. A first series of firing can include firing the firing chambers associated with four nozzles (e.g., nozzles 231-1, 231-7, 233-1, and 233-7). A firing chamber associated with a first nozzle (e.g., nozzle P1-A1231-1) can have a delay of 0 and be fired immediately. A firing chamber associated with a second nozzle (e.g., nozzle P3-A1231-7) can have a firing delay of 1. A firing chamber associated with a third nozzle (e.g., nozzle P2-A1233-1) can have a firing delay of 3 (e.g., (n=4)/2+1). A firing chamber associated with a fourth nozzle (e.g., nozzle P4-A1233-7) can have a firing delay of 4 (e.g., ((n=4)/2)+2).
A second series of firing can occur subsequent to the first firing. The second series of firing can include firing the firing chambers associated with four additional nozzles (e.g., nozzles 231-2, 231-8, 233-2, and 233-8). A firing chamber associated with a fifth nozzle (e.g., nozzle P1-A2231-2) can have a delay of 0 and be fired after the fourth nozzle (e.g., nozzle P4-A1233-7). A firing chamber associated with a sixth nozzle (e.g., nozzle P3-A2231-8) can have a delay of 1 in relation to the fifth nozzle firing. A firing chamber associated with a seventh nozzle (e.g., nozzle P2-A2233-2) can have a delay of 3 (e.g., (n=4)/2+1) in relation to the fifth nozzle firing. A firing chamber associated with an eighth nozzle (e.g., P4-A2233-8) can have a delay of 4 (e.g., ((n−4)/2)+2) in relation to the fifth nozzle firing.
At 343, the method can include firing a number of firing chambers associated with first addresses of each even-numbered primitive of the number of primitives second. For example, a firing chamber associated with a first address of a second primitive (e.g., nozzle 233-1 in
At 345, the method can include firing a number of firing chambers associated with second addresses of each odd-numbered primitive of the number of primitives third. For example, a firing chamber associated with a second address of a first primitive (e.g., nozzle 231-2) can be fired. A firing chamber associated with a second address of a third primitive (e.g., nozzle 231-7) can be fired.
At 347, the method can include firing a number of firing chambers associated with second addresses of each even-numbered primitive of the number of primitives fourth. For example, a firing chamber associated with a second address of a second primitive (e.g., nozzle 233-2) can be fired. A firing chamber associated with a second address of a fourth primitive (e.g., nozzle 233-8) can be fired.
At 349, the method can include firing each of a number of firing chambers associated with subsequently numbered addresses of each odd-numbered primitive before firing each of a number of firing chambers associated with subsequently numbered addresses of each even-numbered primitive. For example, firing chambers associated with a third address of a first primitive (e.g., nozzle 231-3) and a third primitive (e.g., nozzle 231-9) can be fired before firing the firing chambers associated with a third address of a second primitive (e.g., nozzle 233-3) and a fourth primitive (e.g., nozzle 233-9). Further, a firing chamber associated with a fourth address of a first primitive (e.g., nozzle 231-4) can be fired before a firing chamber associated with a fourth address of a second primitive (e.g., 233-4); a firing chamber associated with a fifth address of a first primitive (e.g., nozzle 231-5) can be fired before a firing chamber associated with a fifth address of a second primitive (e.g., nozzle 233-5); and a firing chamber associated with a sixth address of a first primitive (e.g., 231-6) can be fired before a firing chamber associated with a sixth address of a second primitive (e.g., nozzle 233-6).
The firing of the number of firing chambers can be executed by a system including a processor executing instructions stored on a non-transitory machine-readable medium. The system can include a data store, resource management system and/or a number of engines. The resource management system can be in communication with the data store via a communication link, and can include engines. The number of engines can include a combination of hardware and programming that is configured to perform a number of functions described herein (e.g. fire a number of firing chambers). The programming can include program instructions (e.g., software, firmware, etc.) stored in a memory resource (e.g., computer readable medium, machine readable medium, etc.) as well as hard-wired program (e.g., logic).
The system to fire a number of firing chambers can utilize software, hardware, firmware, and/or logic to perform a number of functions described herein. The system can be any combination of hardware and program instructions configured to share information. The hardware, for example can include a processing resource and/or a memory resource (e.g., computer-readable medium, machine readable medium (MRM), database, etc.). A processing resource, as used herein, can include any number of processors capable of executing instructions stored by a memory resource. The processing resource may be integrated in a single device or distributed across multiple devices. The program instructions (e.g., computer-readable instructions (CRI)) can include instructions stored on the memory resource and executable by the processing resource to implement a desired function (e.g., fire a number of firing chambers).
The memory resource can be in communication with a processing resource. A memory resource, as used herein, can include any number of memory components capable of storing instructions that can be executed by processing resource. Such a memory resource can be a non-transitory CRM or MRM. Computer-readable medium may be integrated in a single device or distributed across multiple devices. Further, memory resource may be fully or partially integrated in the same device as processing resource or it may be separate but accessible to that device and processing resource. Thus, it is noted that the system may be implemented on a participant device, on a server device, on a collection of server devices, and/or a combination of the user device and the server device.
The memory resource can be in communication with the processing resource via a communication link (e.g., a path). The communication link can be local or remote to a machine (e.g., a computing device) associated with the processing resource. Examples of a local communication link can include an electronic bus internal to a machine (e.g., a computing device) where the memory resource is one of volatile, non-volatile, fixed, and/or removable storage medium in communication with the processing resource via the electronic bus.
A number of modules can include CRI that when executed by the processing resource can perform a number of functions. The number of modules can be sub-modules of other modules. For example, the historical comparison module and the neighbor comparison module can be sub-modules and/or contained within the same computing device. In another example, the number of modules can comprise individual modules at separate and distinct locations (e.g., CRM, etc.). Each of the number of modules can include instructions that when executed by the processing resource can function as a corresponding engine.
The specification examples provide a description of the applications and use of the system and method of the present disclosure. Since many examples can be made without departing from the spirit and scope of the system and method of the present disclosure, this specification sets forth some of the many possible example configurations and implementations. With regard to the figures, the same part numbers designate the same or similar parts throughout the figures. The figures are not necessarily to scale. The relative size of some parts is exaggerated to more clearly illustrate the example shown.
This is a continuation of U.S. application Ser. No. 15/114,958, having a national entry date of Jul. 28, 2016, which is a national stage application under 35 U.S.C. § 371 of PCT/US2014/014109, filed Jan. 31, 2014, which are both hereby incorporated by reference in their entirety.
Number | Date | Country | |
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Parent | 15114958 | Jul 2016 | US |
Child | 15860958 | US |