Method and apparatus for shifting a bicycle transmission

Abstract

A control mechanism for use with first and second bicycle transmissions includes a transmission position communication path for communicating information indicating the operational positions of the first and second transmissions; a transmission command communication path for communicating information for controlling the operation of the first and second transmissions; a shift command communication path for receiving shift commands to select a speed stage of the bicycle; and a transmission control unit operatively coupled to the shift command communication path, to the transmission position communication path and to the transmission command communication path for receiving the shift commands and the information indicating the operational positions of the first and second transmissions and for generating the information for controlling the operation of the first and second transmissions. When the transmission control unit receives at least one shift command requesting a shift through N speed stages to a destination speed stage, wherein N is an integer greater than one, the transmission control unit generates information for causing the first and second transmissions in combination to move a total of M times to reach the destination speed stage, wherein M is an integer less than N.

Description

BACKGROUND OF THE INVENTION

[0001] The present invention is directed to bicycle control devices and, more particularly, to a method and apparatus for shifting a bicycle transmission.

[0002] Electrically controlled bicycles usually include a front transmission associated with the front pedal assembly, a rear transmission associated with the rear wheel, a motor for each transmission, a control unit for controlling each motor, and a shift control device such as a lever or switch that provides electrical shift command signals to the control unit. The control unit operates the motors for each transmission based on the electrical signals received from the shift control device. In known electrically controlled bicycles, the transmission increases or decreases only one speed stage or gear for each shift command received from the shift control device, and the front or rear transmission operates at least once for each shift command. This can substantially delay the speed change operation and create considerable mechanical noise and wear on the components if the rider wants to shift multiple speed stages at one time.

SUMMARY OF THE INVENTION

[0003] The present invention is directed to a method and apparatus for shifting a bicycle transmission wherein the front and/or rear transmission, at least for some shift commands, can be operated less frequently than known electrically operated bicycles. In one embodiment of the present invention, a control mechanism for use with first and second bicycle transmissions includes a transmission position communication path for communicating information indicating the operational positions of the first and second transmissions; a transmission command communication path for communicating information for controlling the operation of the first and second transmissions; a shift command communication path for receiving shift commands to select a speed stage of the bicycle; and a transmission control unit operatively coupled to the shift command communication path, to the transmission position communication path and to the transmission command communication path for receiving the shift commands and the information indicating the operational positions of the first and second transmissions and for generating the information for controlling the operation of the first and second transmissions. When the transmission control unit receives at least one shift command requesting a shift through N speed stages to a destination speed stage, wherein N is an integer greater than one, the transmission control unit generates information for causing the first and second transmissions in combination to move a total of M times to reach the destination speed stage, wherein M is an integer less than N. The present invention also contemplates a method for operating such transmissions.

[0004] A derailleur-operated bicycle that employs the present invention may include a plurality of front sprockets; a front derailleur for moving a chain among the plurality of front sprockets; a plurality of rear sprockets; a rear derailleur for moving the chain among the plurality of rear sprockets; front and rear derailleur motors for moving the front and rear derailleurs, respectively; and front and rear derailleur position sensors for providing signals indicating the front and rear sprocket positions of the front and rear derailleurs, respectively. The sprocket positions of the front and rear derailleurs set a speed stage of the bicycle. The control unit used with such a bicycle includes a transmission position communication path operatively coupled to the front and rear derailleur position sensors for communicating the signals indicating the front and rear sprocket positions; a transmission command communication path operatively coupled to the front and rear derailleur motors for communicating information for controlling the operation of the front and rear derailleur motors; a shift command communication path for receiving shift commands to set a desired speed stage; and a transmission control unit operatively coupled to the shift command communication path, to the transmission position communication path and to the transmission command communication path for receiving the shift commands and the signals indicating the front and rear sprocket positions and for generating the information for controlling the operation of the front and rear derailleur motors. When the transmission control unit receives at least one shift command requesting a shift through N speed stages to a destination speed stage, where N is an integer greater than one, the transmission control unit generates information for causing the front and rear derailleurs in combination to move a total of M sprocket positions to reach the destination speed stage, where M is an integer less than N. If desired, the sprockets can be selected so that a change of gear ratio when the front derailleur moves from a first front sprocket to a second front sprocket is approximately equal to twice a change of gear ratio when the rear derailleur moves from a first rear sprocket to a second rear sprocket. Such a configuration increases the number of opportunities for shifting multiple steps with fewer transmission movements.

BRIEF DESCRIPTION OF THE DRAWINGS

[0005] FIG. 1 is a side view of a bicycle that includes a particular embodiment of an apparatus according to the present invention for shifting a bicycle transmission;

[0006] FIG. 2 is a block diagram of a particular embodiment of the apparatus according to the present invention for shifting a bicycle transmission;

[0007] FIG. 3A is a timing diagram illustrating a possible electrical shift command signal received by the control unit shown in FIG. 2;

[0008] FIG. 3B is a timing diagram illustrating another possible electrical shift command signal received by the control unit shown in FIG. 2;

[0009] FIG. 3C is a timing diagram illustrating another possible electrical shift command signal received by the control unit shown in FIG. 2;

[0010] FIG. 3D is a timing diagram illustrating a possible composite electrical shift command signal received by the control unit shown in FIG. 2; and

[0011] FIG. 3E is a timing diagram illustrating another possible composite electrical shift command signal received by the control unit shown in FIG. 2.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0012] FIG. 1 is a side view of a bicycle 10 that incorporates a particular embodiment of an apparatus according to the invention for shifting a bicycle transmission. Bicycle 10 may be any type of bicycle, and in this embodiment bicycle 10 includes a typical frame 18 comprising a top tube 22, a head tube 24, a down tube 26 extending downwardly from head tube 24, a seat tube 30 supporting a seat 32 and extending downwardly from top tube 22, a bottom bracket (not shown) disposed at the junction of down tube 26 and seat tube 30, a pair of seatstays 34 extending rearwardly and downwardly from top tube 22, and a pair of chainstays 38 extending rearwardly from the bottom bracket. A fork 42 is rotatably supported within head tube 24, and a front wheel 46 is rotatably supported to the lower end of fork 42. Handlebars 50 control the rotational direction of fork 42 and front wheel 46 in a well-known manner. A rear wheel 54 having a plurality of coaxially mounted rear (freewheel) sprockets 56 is rotatably supported at the junction of seatstays 34 and chainstays 38, and a pedal assembly 58 supporting a plurality of front (chainwheel) sprockets 62 is rotatably supported within the bottom bracket. Typically, two or three front sprockets 62 rotate coaxially and integrally with pedal assembly 58. A chain 66 engages one of the plurality of front sprockets 62 and one of the plurality of rear sprockets 56. A front derailleur 70 moves chain 66 from one front sprocket 62 to another, and a rear derailleur 74 moves chain 66 from one rear sprocket 56 to another. These operations are well known.

[0013] In this embodiment, front derailleur 70 is controlled by pulling and releasing a conventional Bowden-type control cable 78 coupled to a front derailleur motor 82 (FIG. 2) disposed in a motor assembly 84, and rear derailleur 74 is controlled by pulling and releasing a Bowden-type control cable 86 coupled to a rear derailleur motor 88 disposed in motor assembly 84. Of course, in some embodiments a single motor may be coupled to separate cable pulling structures through clutches or otherwise to perform the same function, and such also could be deemed distinct motors. A front derailleur position sensor 87 and a rear derailleur position sensor 88 are provided for sensing the operational positions of the front and rear derailleurs 70 and 74, respectively. These position sensors provide signals that, in turn, determine which front sprocket 62 and rear sprocket 56 is currently engaged by chain 66. Such position sensors may comprise, for example, known potentiometers for sensing the positions of the output shafts of front derailleur motor 82 and rear derailleur motor 88, but there are many other known structures that can perform these functions. A speed sensor 91 is mounted to fork 42 for receiving signals from a magnet 89 mounted to front wheel 46 for sensing the speed of the bicycle in a well-known manner, and a cadence sensor 92 is mounted to pedal assembly 58 for receiving signals from a magnet 93 mounted to one of the chainstays 38 for sensing the pedal cadence in a well known manner.

[0014] A transmission control unit 90 is operatively coupled to motor assembly 84 through a transmission command communication path 94 and to position sensors 87 and 88 through a transmission position communication path 96 for generating transmission command (TC) signals for controlling the operation of motor assembly 84 in accordance with the information from position sensors 87 and 88. A manually operated shift command unit 98, comprising a shift-up switch 98A and a shift-down switch 98B, is operatively coupled to transmission control unit 90 through a shift command communication path 102 for communicating electrical shift commands (described in more detail below) to transmission control unit 90. Furthermore, an automatic shift command unit 103 is operatively coupled to transmission control unit 90 through shift command communication path 102, to position sensors 87 and 88 through transmission position communication path 96, to speed sensor 91 through a speed communication path 105, and to cadence sensor 92 through a cadence communication path 106 for communicating electrical shift commands to transmission control unit 90 in accordance with signals received from position sensors 87 and 88, speed sensor 91 and/or cadence sensor 92. Such shift commands may comprise the shift commands described below for shift command unit 98, or they may comprise digital messages. Automatic shift command unit 103 includes a parameter memory 107 for storing wheel circumference, cadence tables, speed tables and/or acceleration tables for generating shift commands based on cadence, speed and/or acceleration in accordance with known programming techniques. Parameter memory 107 may be a hardware table memory, a software table memory, or some other structure that provides the same information. Other inputs 110 may be operatively coupled to automatic shift command unit 103 through a communication path 112 for communicating other information such as from a heart rate sensor, a slope sensor, a pedal or other torque sensor, etc. Parameter memory 107 and the programming of automatic shift command unit 103 may be configured accordingly to generate shift commands in accordance with these other inputs in any combination. Of course, in some embodiments only manually operated shift command unit 98 may be provided, and in other embodiments only automatic shift command unit 103 may be provided. In this embodiment, communication paths 94, 96, 102, 105 and 106 have the form of electrical wires, but in other embodiments such communication paths may comprise fiber optic devices, wireless communication paths, or some other mechanism.

[0015] According to the present invention, when the transmission control unit 90 receives at least one shift command requesting a shift through N speed stages to a destination speed stage, wherein N is an integer greater than one, transmission control unit 90 generates TC signals (digital or analog) for causing front derailleur 70 and rear derailleur 74 in combination to move a total of M times to reach the destination speed stage, wherein M is an integer less than N. To accomplish this, transmission control unit 90 comprises a table memory 110 for storing a table containing the information for controlling the operation of front derailleur 70 and rear derailleur 74. Table memory 110 may be a hardware table memory, a software table memory, or some other structure that provides the same information. The content of table memory 110 depends upon the configuration of the bicycle. Three examples will be provided below, and other configurations will be readily apparent to one of ordinary skill in the art.

[0016] FIGS. 3A-3E are timing diagrams indicating various embodiments of shift commands generated by shift control unit 98 and the timing of TC signals generated by transmission control unit 90. In each diagram, the shift command signals are low active. FIG. 3A illustrates a situation wherein a shift command signal is generated by shift control device 98 for a time interval P that is less than a predetermined time interval X. In this embodiment, such a shift command signal is assumed to be a spurious signal, and no operation is performed. Of course, in other embodiments such a shift command signal could perform some kind of function. FIG. 3B illustrates a situation wherein a shift command signal is generated by shift control device 98 for a time interval Q that is greater than time interval X. In this embodiment, such a shift command signal requests a shift by one speed stage, and the TC signal is generated accordingly. FIG. 3C illustrates a situation wherein a shift command signal is generated by shift control device 98 for a time interval R that is greater than time interval X and also greater than a time interval Y, wherein, for the purposes of measurement, time interval Y begins at the same instant as time interval X but is greater than time interval X. In this embodiment, such a shift command signal requests a shift by two speed stages, and the TC signal is generated accordingly.

[0017] FIG. 3D illustrates a situation wherein a composite shift command signal appearing on two channels is generated by shift control device 98. In this example, the shift command signal appearing on channel A is generated for a time interval S that is greater than time interval X. A shift command signal is generated on channel B prior to the expiration of time interval Y. In this embodiment, such a composite shift command signal requests a shift by two speed stages, and the TC signal is generated accordingly. Such a composite signal could be generated by two separately operated switches, but in most cases it would be more convenient to generate such signals by a plunger with an electrical contact which successively and cumulatively contacts two other electrical contacts. Such a switch also could be used to generate the signal shown in FIGS. 3A-3C by depressing the plunger only enough to activate one of the two other electrical contacts. Of course, many ways of generating such signals could be devised. FIG. 3E illustrates a situation wherein sequential shift command signals are generated by shift control device 98. In this example, two sequential shift command signals are generated within a time interval T of each other. Such an action is similar to double-clicking a computer mouse. In this embodiment, such sequential shift command signals request a shift by two speed stages, and the TC signal is generated accordingly. Each shift-up switch 98A and shift-down switch 98B may use any of the techniques illustrated in FIGS. 3A-3E to suit the application.

[0018] Automatic shift command unit 103 may generate the signals illustrated in FIGS. 3B-3E for the same purposes described for them, or it may generate digital messages. Digital messages would be particularly useful to request a shift through more than two speed stages, although manual shift command unit 98 could be configured to provide signals for that purpose as well. The signals generated by automatic shift command unit 103 representing shifts through multiple speed stages could be generated based on cadence, speed, acceleration, or some other criteria.

[0019] Table 1 illustrates a bicycle with two front sprockets 62 and eight rear sprockets 56, and Table 2 illustrates the shift commands and TC signals for operating front derailleur 70 and rear derailleur 74 for this configuration. Transmission control unit 90 is programmed, whether through hardwired logic, software or otherwise to generate the appropriate TC signals on communication path 94 in response to the indicated shift command. 1 TABLE 1 Rear Sprocket Teeth 11 13 15 17 21 25 29 33 Front 46 4.18 3.54 3.07 2.71 2.19 1.84 1.59 1.39 Sprock- 34 3.09 2.62 2.27 2.00 1.62 1.36 1.17 1.03 et

[0020] 2 TABLE 2 Present Gear Signal Recognized By Control Unit Position Two Steps Two Steps One Step Front Rear Up One Step Up Down Down 46 11 Alarm Alarm front − 1 rear − 1 46 13 rear + 1 rear + 1 front − 1 rear − 1 46 15 rear + 2 rear + 1 front − 1 rear − 1 46 17 rear + 2 rear + 1 front − 1 rear − 1 46 21 rear + 2 rear + 1 front − 1 rear − 1 46 25 rear + 2 rear + 1 front − 1 rear − 1 46 29 rear + 2 rear + 1 front − 1 rear − 1 46 33 rear + 2 rear + 1 front − 1 front − 1 rear + 1 34 11 front + 1 front + 1, rear − 2 rear − 1 rear − 1 34 13 front + 1 rear + 1 rear − 2 rear − 1 34 15 front + 1 rear + 1 rear − 2 rear − 1 34 17 front + 1 rear + 1 rear − 2 rear − 1 34 21 front + 1 rear + 1 rear − 2 rear − 1 34 25 front + 1 rear + 1 rear − 2 rear − 1 34 29 front + 1 rear + 1 rear − 1 rear − 1 34 33 front + 1 rear + 1 Alarm Alarm Speed Stage

[0021] Table 3 illustrates a bicycle with three front sprockets 62 and eight rear sprockets 56, and Table 4 illustrates the shift commands and TC signals for operating front derailleur 70 and rear derailleur 74 for this configuration. 3 TABLE 3 Rear Sprocket Teeth 11 13 15 17 21 25 29 33 Front 46 4.18 3.54 3.07 2.71 2.19 1.84 1.59 1.39 Sprock- 34 3.09 2.62 2.27 2.00 1.62 1.36 1.17 1.03 et 24 2.18 1.85 1.60 1.41 1.14 0.96 0.83 0.73

[0022] 4 TABLE 4 Present Gear Signal Recognized By Computer Position Two Steps Two Steps One Step Front Rear Up One Step Up Down Down 46 11 Alarm Alarm front − 1 rear − 1 46 13 rear + 1 rear + 1 front − 1 rear − 1 46 15 rear + 2 rear + 1 front − 1 rear − 1 46 17 rear + 2 rear + 1 front − 1 rear − 1 46 21 rear + 2 rear + 1 front − 1 rear − 1 46 25 rear + 2 rear + 1 front − 1 rear − 1 46 29 rear + 2 rear + 1 front − 1 rear − 1 46 33 rear + 2 rear + 1 front − 1 front − 1 rear + 1 34 11 front + 1 front + 1, front − 1 rear − 1 rear − 1 34 13 front + 1 rear + 1 front − 1 rear − 1 34 15 front + 1 rear + 1 front − 1 rear − 1 34 17 front + 1 rear + 1 front − 1 rear − 1 34 21 front + 1 rear + 1 front − 1 rear − 1 34 25 front + 1 rear + 1 front − 1 rear − 1 34 29 front + 1 rear + 1 front − 1 rear − 1 34 33 front + 1 rear + 1 front − 1 front − 1, rear + 1 24 11 front + 1 front + 1, rear − 2 rear − 1 rear − 1 24 13 front + 1 rear + 1 rear − 2 rear − 1 24 15 front + 1 rear + 1 rear − 2 rear − 1 24 17 front + 1 rear + 1 rear − 2 rear − 1 24 21 front + 1 rear + 1 rear − 2 rear − 1 24 25 front + 1 rear + 1 rear − 2 rear − 1 24 29 front + 1 rear + 1 rear − 1 rear − 1 24 33 front + 1 rear + 1 Alarm Alarm Speed Stage

[0023] Table 5 illustrates the shift commands and TC signals for operating front derailleur 70 and rear derailleur 74 for the same configuration when implementing the concept of a prohibited range of sprocket combinations. Such prohibited sprocket combinations typically comprise the combination of the large front sprocket with the large rear sprockets, which results in excessive chain tension, and the small front sprocket with the small rear sprockets, which results in excessive chain looseness. 5 TABLE 5 Present Gear Signal Recognized By Computer Position Two Steps Two Steps One Step Front Rear Up One Step Up Down Down 46 11 Alarm Alarm front − 1 rear − 1 46 13 rear + 1 rear + 1 front − 1 rear − 1 46 15 rear + 2 rear + 1 front − 1 rear − 1 46 17 rear + 2 rear + 1 front − 1 rear − 1 46 21 rear + 2 rear + 1 front − 1 front − 1, rear + 1 46 25 Prohibited Prohibited Prohibited Prohibited 46 29 Prohibited Prohibited Prohibited Prohibited 46 33 Prohibited Prohibited Prohibited Prohibited 34 11 front + 1 front + 1, rear − 2 rear − 1 rear − 1 34 13 front + 1 rear + 1 rear − 2 rear − 1 34 15 front + 1 rear + 1 rear − 2 rear − 1 34 17 front + 1 rear + 1 front − 1 rear − 1 34 21 front + 1 rear + 1 front − 1 rear − 1 34 25 rear + 2 rear + 1 front − 1 rear − 1 34 29 rear + 2 rear + 1 front − 1 rear − 1 34 33 rear + 2 rear + 1 front − 1 front − 1, rear + 1 24 11 Prohibited Prohibited Prohibited Prohibited 24 13 Prohibited Prohibited Prohibited Prohibited 24 15 Prohibited Prohibited Prohibited Prohibited 24 17 front + 1 front + 1, rear − 2 rear − 1 rear − 1 24 21 front + 1 rear + 1 rear − 2 rear − 1 24 25 front + 1 rear + 1 rear − 2 rear − 1 24 29 front + 1 rear + 1 rear − 1 rear − 1 24 33 front + 1 rear + 1 Alarm Alarm Speed Stage

[0024] In all examples, it should be noticed that some shift commands that request a change through two speed stages require only one movement of one derailleur. For example, assume in the first configuration that chain 66 is disposed on the 34-tooth front sprocket 62 and the 33-tooth rear sprocket 56, thus producing a speed stage having a gear ratio of 1.03. If shift control device 98 generates a signal indicating a two-step-up shift command (two sequential gear ratios), then transmission control unit 90 may generate a TC signal to move front derailleur 70 a single step so that chain 66 engages the 46-tooth front sprocket 62, thus producing the speed stage having a gear ratio of 1.39. Prior art electrically controlled bicycles would move rear derailleur 74 from the 33-tooth rear sprocket 56 to the 29-tooth rear sprocket 56, and then to the 25-tooth rear sprocket 56, thus producing the speed stage having a gear ratio of 1.36. Such a technique requires a total of two movements, rather than the one movement taught herein.

[0025] The method and apparatus according to the present invention takes advantage of the fact that many front/rear sprocket combinations produce substantially the same gear ratio. The TC signals are generated based on which combination of front and rear sprockets require the least number of movements of the front derailleur 70 and/or rear derailleur 74 to achieve the desired gear ratio. In general, particularly good results can be achieved by selecting the front and rear sprockets such that, for a given combination of front and rear sprockets, the change in gear ratio that results when switching from one front sprocket to another front sprocket is substantially an integral number of the change in gear ratio when switching from one rear sprocket to another rear sprocket. In the embodiment disclosed above, the change in gear ratio that results when switching from one front sprocket to another front sprocket is substantially twice the change in gear ratio when switching from one rear sprocket to another rear sprocket. If a shift command signal is received that cannot be accommodated, such as a shift-up command to when the chain 66 currently engages the largest front sprocket 62 and the smallest rear sprocket 56, then table memory 110 can instruct the system to sound an audible alarm indicating an illegal request. In such a situation front derailleur 70 and rear derailleur 74 remain stationary.

[0026] While the above is a description of various embodiments of the present invention, further modifications may be employed without departing from the spirit and scope of the present invention. For example, the size, shape, location or orientation of the various components may be changed as desired. The functions of one element may be performed by two, and vice versa. It is not necessary for all advantages to be present in a particular embodiment at the same time. Every feature which is unique from the prior art, alone or in combination with other features, also should be considered a separate description of further inventions by the applicant, including the structural and/or functional concepts embodied by such feature(s). Thus, the scope of the invention should not be limited by the specific structures disclosed or the apparent initial focus on a particular structure or feature.

Claims

1. An apparatus for controlling a first bicycle transmission and a second bicycle transmission which, in combination, sets a speed stage of the bicycle, comprising:

a transmission position communication path for communicating information indicating the operational position of the first transmission and the second transmission;

a transmission command communication path for communicating information for controlling the operation of the first transmission and the second transmission;

a shift command communication path for communicating shift commands to select a speed stage of the bicycle;

a transmission control unit operatively coupled to the shift command communication path, to the transmission position communication path and to the transmission command communication path for receiving the shift commands and the information indicating the operational position of the first transmission and the second transmission and for generating the information for controlling the operation of the first transmission and the second transmission;

wherein, when the transmission control unit receives at least one shift command requesting a shift through N speed stages to a destination speed stage, where N is an integer greater than one, the transmission control unit generates information for causing the first transmission and the second transmission in combination to move a total of M times to reach the destination speed stage, where M is an integer less than N.

2. The apparatus according to claim 1 wherein the information for controlling the operation of the first transmission and the second transmission comprises a first signal for operating a front derailleur and a second signal for operating a rear derailleur.

3. The apparatus according to claim 1 wherein the transmission control unit comprises a table memory for storing a table containing the information for controlling the operation of the first transmission and the second transmission.

4. The apparatus according to claim 3 wherein the first transmission moves to X first transmission positions, wherein the second transmission moves to Y second transmission positions, wherein X any Y both are integers greater than 1, and wherein the table memory contains information for controlling the operation of at least one of the first transmission and the second transmission for each X first transmission position and for each Y second transmission position.

5. The apparatus according to claim 4 wherein the table memory contains information for moving only one of the first transmission and the second transmission by only one of the corresponding first transmission positions and second transmission positions to reach the destination speed stage in response to a shift command requesting a shift through N speed stages to reach the destination speed stage.

6. The apparatus according to claim 4 wherein the table memory contains information for controlling the operation of at least one of the first transmission and the second transmission for shift commands requesting a shift through a single speed stage and for shift commands requesting a shift through N speed stages.

7. The apparatus according to claim 4 wherein the table memory contains information for maintaining both the first transmission and the second transmission stationary in response to a shift command requesting a shift through N speed stages to reach the destination speed stage.

8. The apparatus according to claim 1 wherein the shift command requesting a shift through N speed stages comprises a first command signal and a second command signal, wherein the first command signal and the second command signal occur simultaneously.

9. The apparatus according to claim 8 wherein the first command signal occurs prior to the second command signal.

10. The apparatus according to claim 1 wherein the shift command requesting a shift through N speed stages comprises a first command signal and a second command signal, wherein the first command signal and the second command signal occur within a prescribed time interval.

11. The apparatus according to claim 10 wherein the occurrences of the first command signal and the second command signal are not simultaneous.

12. The apparatus according to claim 1 wherein the shift command requesting a shift through N speed stages comprises a command signal that occurs for a time interval greater than a prescribed value.

13. The apparatus according to claim 1 further comprising a manually-operated shift control unit operatively coupled to the shift command communication path.

14. The apparatus according to claim 1 further comprising:

a speed sensor operatively coupled to a speed communication path; and

an automatic shift control unit operatively coupled to the speed communication path and to the shift command communication path for automatically generating shift commands based on information received from the speed sensor.

15. The apparatus according to claim 14 wherein the automatic shift control unit generates shift commands based on bicycle speed.

16. The apparatus according to claim 14 wherein the automatic shift control unit generates shift commands based on bicycle acceleration.

17. The apparatus according to claim 1 further comprising:

a cadence sensor operatively coupled to a cadence communication path; and

an automatic shift control unit operatively coupled to the cadence communication path and to the shift command communication path for automatically generating shift commands based on information received from the cadence sensor.

18. The apparatus according to claim 1 further comprising:

a manually-operated shift control unit operatively coupled to the shift command communication path;

a speed sensor operatively coupled to a speed communication path; and

an automatic shift control unit operatively coupled to the speed communication path and to the shift command communication path for automatically generating shift commands based on information received from the speed sensor.

19. The apparatus according to claim 1 further comprising:

a manually-operated shift control unit operatively coupled to the shift command communication path;

a cadence sensor operatively coupled to a cadence communication path; and

an automatic shift control unit operatively coupled to the cadence communication path and to the shift command communication path for automatically generating shift commands based on information received from the cadence sensor.

20. A bicycle transmission comprising:

a plurality of front sprockets;

a front derailleur for moving a chain among the plurality of front sprockets;

a front derailleur motor for moving the front derailleur;

a plurality of rear sprockets;

a rear derailleur for moving the chain among the plurality of rear sprockets;

a rear derailleur motor for moving the rear derailleur;

a front derailleur position sensor for providing a signal indicating a front sprocket position of the front derailleur;

a rear derailleur position sensor for providing a signal indicating a rear sprocket position of the rear derailleur;

wherein the front sprocket position of the front derailleur and the rear sprocket position of the rear derailleur set a speed stage of the bicycle transmission;

a transmission position communication path operatively coupled to the front derailleur position sensor and to the rear derailleur position sensor for communicating the signals indicating the front sprocket position and the rear sprocket position;

a transmission command communication path operatively coupled to the front derailleur motor and to the rear derailleur motor for communicating information for controlling the operation of the front derailleur motor and the rear derailleur motor;

a shift command communication path for receiving shift commands to set a desired speed stage;

a transmission control unit operatively coupled to the shift command communication path, to the transmission position communication path and to the transmission command communication path for receiving the shift commands and the signals indicating the front sprocket position and the rear sprocket position and for generating the information for controlling the operation of the front derailleur motor and the rear derailleur motor;

wherein, when the transmission control unit receives at least one shift command requesting a shift through N speed stages to a destination speed stage, where N is an integer greater than one, the transmission control unit generates information for causing the front derailleur and the rear derailleur in combination to move a total of M sprocket positions to reach the destination speed stage, where M is an integer less than N.

21. The transmission according to claim 20 wherein a change of gear ratio when the front derailleur moves from a first front sprocket to a second front sprocket is approximately equal to twice a change of gear ratio when the rear derailleur moves from a first rear sprocket to a second rear sprocket.

22. A method for controlling a first bicycle transmission and a second bicycle transmission which, in combination, sets a speed stage of the bicycle, comprising the steps of:

receiving, by a transmission control unit, information indicating the operational position of the first transmission and the second transmission;

receiving, by the transmission control unit, at least one shift command requesting a shift through N speed stages to a destination speed stage, wherein N is an integer greater than one; and

generating, by the transmission control unit, information for causing the first transmission and the second transmission in combination to move a total of M times to reach the destination speed stage, wherein M is an integer less than N.

23. The method according to claim 22 wherein the information for controlling the operation of the first transmission and the second transmission comprises a first signal for operating a front derailleur and a second signal for operating a rear derailleur.

24. The method according to claim 22 further comprising the step of storing a table containing the information for controlling the operation of the first transmission and the second transmission.

25. The method according to claim 24 wherein the first transmission moves to X first transmission positions, wherein the second transmission moves to Y second transmission positions, wherein X any Y both are integers greater than 1, and wherein the storing step comprises the step of storing information for controlling the operation of at least one of the first transmission and the second transmission for each X first transmission position and for each Y second transmission position.

26. The method according to claim 25 wherein the storing step further comprises the step of storing information for moving only one of the first transmission and the second transmission by only one of the corresponding first transmission positions and second transmission positions to reach the destination speed stage in response to a shift command requesting a shift through N speed stages to reach the destination speed stage.

27. The method according to claim 25 wherein the storing step further comprises the step of storing information for controlling the operation of at least one of the first transmission and the second transmission for shift commands requesting a shift through a single speed stage and for shift commands requesting a shift through N speed stages.

28. The method according to claim 25 wherein the storing step further comprises the step of storing information for maintaining both the first transmission and the second transmission stationary in response to a shift command requesting a shift through N speed stages to reach the destination speed stage.

29. The method according to claim 22 wherein the shift command requesting a shift through N speed stages comprises a first command signal and a second command signal, wherein the first command signal and the second command signal occur simultaneously.

30. The method according to claim 29 wherein the first command signal occurs prior to the second command signal.

31. The method according to claim 22 wherein the shift command requesting a shift through N speed stages comprises a first command signal and a second command signal, wherein the first command signal and the second command signal occur within a prescribed time interval.

32. The method according to claim 31 wherein the occurrences of the first command signal and the second command signal are not simultaneous.

33. The method according to claim 22 wherein the shift command requesting a shift through N speed stages comprises a command signal that occurs for a time interval greater than a prescribed value.

34. The method according to claim 22 further comprising the step of manually generating the at least one shift command.

35. The method according to claim 22 further comprising the steps of:

receiving, by an automatic shift command unit, information from a speed sensor; and

automatically generating shift commands based on information received from the speed sensor.

36. The method according to claim 35 wherein the step of automatically generating shift commands comprises the step of generating shift commands based on bicycle speed.

37. The method according to claim 35 wherein the step of automatically generating shift commands comprises the step of generating shift commands based on bicycle acceleration.

38. The method according to claim 22 further comprising the steps of:

receiving, by an automatic shift command unit, information from a cadence sensor; and

automatically generating shift commands based on information received from the cadence sensor.