1. Technical Field
The present invention relates generally to transceiver modules. More particularly, an exemplary embodiment of the invention is concerned with a 10 Gb/s XFP transceiver that includes 8.5 Gb/s CDR bypass functionality.
2. Background of the Invention
The proliferation and significance of networking technology is well known. The ever-increasing demand for network bandwidth has resulted in the development of technology that increases the amount of data traveling across a network. Advancements in modulation techniques, coding algorithms and error correction have drastically increased rates of this data. For example, a few years ago, the highest rate that data could travel across a network was at approximately one Gigabit per second (Gb/s). This rate has increased ten-fold today where data travels across Ethernet and SONET (Synchronous Optical Network) networks at upwards of 10 Gb/s. For instance, the XFP (10 Gb/s serial electrical interface) Pluggable Module Multi-Source Agreement is directed at transceivers operating at approximately 10 Gb/s.
In operation, a serial optical data stream received by the transceiver module 100 is converted to an electrical serial data stream by the receiver 115. This electrical serial data stream is deserialized by the SERDES 110 into four channels and transmitted via the parallel bus 140 to the host 105 for processing. This deserialization occurs in order to prevent further bandwidth degradation of the electrical data stream and stay below a jitter budget as it continues to travel along the data path. A high data rate electrical signal (e.g., 10 Gb/s) is more easily distorted by imperfections within the data path and by the inductance of the bus and connections along the data path. Reflections caused by discontinuities within a transmission line and amplitude degradations caused by nodes within a path (e.g., wire bond, solder bump, etc.) may significantly increase errors within the signal and increase jitter beyond an acceptable threshold or budget. Additionally, inductance is proportionally more severe at higher frequencies. Thus, the data stream is deserialized onto parallel transmission lines in order to reduce the rate on each of these lines and minimize degradation along the data path.
A similar deserialization occurs on the transmit side of the transceiver module 100 for the same reasons described above. In particular, a deserialized electrical data stream is transferred from the host 105 to the second SERDES 120 via parallel bus 145. The second SERDES 120 serializes this electrical signal. The transmitter 125 converts the serial electrical signal to an optical signal and transmits it onto the network.
One drawback of module 100 is that the SERDES 110, 120 and the interfaces to the parallel buses 140, 145 require a relatively large amount of space on the transceiver module 100. Additionally, SERDES consume power and release a relatively large amount of heat. Another drawback of module 100 is that conventional transceiver modules do not include convenient, cost-effective means to monitor the status of data paths and confirm proper operation of the transceiver.
Fiberoptic modules operating at data rates less than 10 Gb/s commonly employ serial electrical interfaces without any means of resetting the jitter budget at the inputs and outputs of the module 100. The most common data rates for these modules are at 1.0625 Gb/s for Fibre Channel, 1.25 Gb/s for Gigabit Ethernet, 2.125 Gb/s for double-rate Fibre Channel, 2.48 Gb/s for OC-48, 2.7 Gb/s for forward error correction (“FEC”) rates of OC-48, and numerous rates less than 1 Gb/s for other applications. Serial modules are also used for proprietary links at data rates from less than 1 Gb/s to about 3.125 Gb/s. At these relatively low data rates, there is no need to perform reshaping or retiming of the data at the electrical inputs and outputs (“I/Os”) of the module because the signal degradations at those data rates are sufficiently small. However, at data rates approaching or exceeding 10 Gb/s, the bit periods become sufficiently short so that signal degradations are difficult to minimize using conventional approaches to serial modules. Additionally, serial modules at data rates lower than 10 Gb/s can have digital or analog monitoring functions, but the types of error monitoring or diagnostic features that are possible in a module incorporating an integrated SERDES have not thus far implemented.
Moreover, the XFP standard requires that transceiver modules handle data rates of approximately 10 Gb/s, while outputting to the host through a serial interface among other things. Particularly, an XFI (10 Gb/s serial electrical interface) is designed for serial input from an XFP transceiver. This allows host designers and manufacturers to supply host systems assuming that XFP transceivers will perform the discussed functions.
Therefore, it is desirable to provide a transceiver module capable of handling 10 Gb/s data input from a network within a jitter budget. It is further desirable to provide a transceiver module that interfaces with a host using serial connections, thereby allowing the removal of SERDES components from the module. Additionally, it is desirable to provide additional functionality, for example error monitoring functionality that is integrated within the transceiver module that would identify errors and perform bit error rate tests (“BERTs”) within a data path and/or component on the module.
The present invention overcomes the limitations of the prior art by providing a transceiver module with eye diagram opening functionality for reducing jitter. In one implementation, an optical transceiver module has a serial electrical interface with an electrical output port and an electrical input port. The module also has a receive path and a transmit path. The receive path includes an optical input port, a receiver eye opener and the electrical output port of the serial electrical interface. An optical signal is received by the module at the optical input port. The receiver eye opener retimes and reshapes a serial electrical data stream based on the received optical signal. The retimed and reshaped serial electrical data stream is transmitted from the module via the electrical output port. The transmit path includes the electrical input port of the serial electrical interface, a transmitter eye opener and an optical output port. A second serial electrical data stream is received by the module at the electrical input port. The transmitter eye opener retimes and reshapes the received serial electrical data stream. An optical signal based on the retimed and reshaped serial electrical data stream is transmitted from the module via the optical output port.
In one implementation, the receiver eye opener and the transmitter eye opener are implemented in a single integrated circuit. The integrated circuit may also include none, some or all of the following: digital to analog converters for example for converting received digital signals to analog control signals, a bypass module for example for bypassing the eye opener(s) under certain conditions, loopback data paths for example for performing diagnostic tests, bit error rate (BERT) tester, adaptive equalizer(s) for example for conditioning the serial data streams, power amplifier or other components for the receiver, driver (e.g., laser driver) or other components for the transmitter, a control module and/or a serial control interface for controlling the circuitry. The integrated circuit may also include various power down or reduced power modes in order to conserve energy. In another aspect, the data path(s) may include two or more eye openers, each suited for a different data rate. Switching between the eye openers permits the accommodation of different data rates.
Other aspects of the invention include applications, systems and methods corresponding to the devices described above.
To further clarify the above and other aspects of embodiments of the present invention, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. These drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope. In addition, the drawings are not drawn to scale. The invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
An apparatus and method for providing serial connections between a transceiver module and host is described. In particular, clock and data recovery and error monitoring functionality is integrated on the transceiver module that allows these serial connections. One skilled in the art will recognize that embodiments of the present invention and description below may also be incorporated within a transponder module. In the following description, for purposes of explanation, specific details are set forth in order to provide an understanding of the invention. It will be apparent, however, to one skilled in the art that the invention can be practiced without these details. In other instances, structures and devices are shown in block diagram form in order to avoid obscuring the invention.
Reference in the specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. The appearances of the phrase “in one embodiment” in various places in the specification are not necessarily all referring to the same embodiment.
The receiver eye opener 205b extracts a clock from the electrical signal and uses that recovered clock to regenerate degraded data within the signal. In particular, the receiver eye opener 205b provides retiming and reshaping that removes jitter (i.e., resets the jitter budget in the link). The retiming and reshaping function of the eye opener 205 may be implemented by a clock and data recovery (“CDR”) and a retimer (“RT”), a signal conditioner, or any device capable of opening the eye diagram. Both passive and adaptive equalization circuits may be used for these purposes. The eye opener 205 is preferably responsive to the data rate of the data stream on the particular path. According to one embodiment, the receiver eye opener 205b includes a phase locked loop that aligns the phase of the electrical signal with a reference clock to ensure that the electrical signal is correctly clocked, and a signal shaper that filters noise from the signal and more accurately shapes the pulse edges in the signal. The eye openers 205a,b may be implemented as ASICs, as a configurable circuit such as an FPGA, or partly in software, to name but a few possibilities. One skilled in the art will recognize that there are numerous methods for providing eye opening functionality that operate in accordance with the present invention. After the electrical signal has been properly synchronized and shaped by the receiver eye opener 205b, it is transmitted to the host 105 via a serial path 260 such as an XFI-compliant 10 Gb/s transmission line.
Other advantageous functions may also be implemented herein along with the eye openers 205a,b. In some embodiments, bypass, also known as “pass-through”, functions are incorporated in the eye openers 205a, 205b which allow the data to bypass the retiming and reshaping functions of the eye opener. These bypass functions can be automatically selected, for instance by use of a loss of lock (“LOL”) signal, or selectable with a control line or digital control. The eye openers 205a, 205b may also have low power modes (power down modes) that are enabled via a control pin, or by control through a digital bus or two wire interface. The eye openers 205a, 205b may also have BERT functions whereby a BERT engine within the eye opener generates data and/or an error detector matches up incoming data to a predetermined pattern to check for errors in the data stream. In addition, the eye openers 205a, 205b may have loopback functions that allow the data to be looped back with the addition of some signal I/Os between the eye opener. For instance, data from eye opener 205b may be routed over to eye opener 205a and this data transmitted to the transmitter 225 in place of the data from data path 250. In some combinations, these features allow the transceiver to perform self-test, or diagnostics of the data link, or diagnostics of the host system. These functionalities will be discussed in more detail below.
The transmit path includes a transmitter 225 coupled to a network and a transmitter eye opener 205a. The transmitter eye opener 205a recovers degraded clock and data values from an electrical signal that travels from the host 105 via serial path 250 (e.g., 10 G/s transmission line). As described above, the electrical signal will degrade along this path 250 and the eye opener 205a compensates for this degradation and sends the electrical signal to the transmitter 225. The transmitter 225 includes a transmitter optical sub-assembly (“TOSA”) 245 that converts an electrical signal to an optical signal and transmits it onto a network. The transmitter 225 also preferably includes a laser driver 240 that controls a laser within the TOSA 245 and the modulation of data within the electrical signal onto the optical signal. The laser within the TOSA 245 is also biased to the proper operating current using a dedicated biasing and control circuit that may be contained within or outside of the laser driver. The transmitter 225 may include eye opener 205a depending on the particulars of the packaging and design chosen.
This transceiver module 200 allows serial connections 250, 260 between the transceiver module 200 and the host 105. In particular, the receiver and transmitter eye openers 205a, 205b compensate, on for signal degradation that occurs on these serial connections 250, 260 at high data rates, such as a data rate of about 10 Gb/s or higher.
The eye opener IC 205b provides a not ready signal to the host. One condition that activates the not ready signal is a result of a loss of signal (“LOS”) signal. A first input of control logic 999b receives the LOS signal from an output of the buffer 945b when the buffer 945b does not detect incoming data. Another condition that activates the not ready signal as a result of a LOL signal. A second input of the control logic 999b receives the LOL signal from an output of CDR 925b when the CDR 925b is not able to lock onto the signal such as when the data rate is outside of the CDR 925b's range. The control logic may, for example, be implemented as OR gate logic.
A MUX 955b provides bypass functionality to the data path. The output of buffer 945b is coupled to a first input of the MUX 955b. A second input of the MUX 955b is the retimed and reshaped data output of RT 935b. The control logic 999b sends a control signal to the selector input of the MUX 955b to select either the first or second input. The control logic 999b selects the buffered data from buffer 945b in response to receiving a LOL, an LOS, or bypass signal (e.g., from the host). In this embodiment, the control logic 999b selects the output RT 935b as a default condition.
A polarity control coupled to the input of the buffer 945a changes the polarity of its output signal, which is preferably composed of differential signaling. Also, the buffer 945d is preferably a coupled mode logic buffer and the buffer 945h is preferably a positive emitter coupled logic buffer.
The eye opener IC 205a includes control logic 999a to implement the not ready signal. A MUX 955a implements the bypass functionality.
A MUX 955g allows the retimer 935a to retime the data in synchronization with a Tx clock provided, in one example, by the host. A first input of the MUX 955g receives a ref clock signal for use by the RT 925a as a starting point in retiming the data. A second input of the MUX 955g receives a Tx clock signal, which is preferably a high-quality signal that may be used for retiming the data in place of the recovered clock signal. The Tx clock frequency may be adjusted by a clock multiplier unit as indicated by a rate select pin. The MUX 955g selects between the ref clock signal and the Tx clock signal according to a clock select signal. In one embodiment, the clock select signal is transmitted over a serial line along with other signals instead of through a dedicated pin.
In addition, the receiver eye opener 205b and the transmitter eye opener 205a can share the single reference clock 320. Accordingly, this integration reduces the number of inputs or pins on the chip itself, allows for easier testing of the chip, and reduces the number of components. Reference clock 320 is usually an input from the host board and is a clock at a sub-harmonic of the data rate. While it is possible to maintain the clock at exactly the data rate, this may not be desirable for signal integrity and EMI reasons. Generally the reference clock is 1/16th or 1/64th of the data rate. In some operating modes of the transceiver it would be possible to use the recovered clock from the receiver eye opener 205b as the reference clock of the transmitter eye opener 205a. Alternately, the reference clock input to eye opener 205b can be internally rerouted to act as the reference clock 320 for the receiver eye opener 205b. In either case, a reference clock 320 is still supplied by the host board.
In other embodiments, the receiver 115, the transmitter 125, or portions thereof (e.g. post-amplifier or laser driver) may be integrated onto the chip as described below.
A pass-through control 377 allows the eye opener control module 350 to activate/deactivate the receiver eye opener 205b and the transmitter eye opener 205a to allow data streams that are incompatible with a data rate range of a particular eye opener to pass through the transceiver module 200. For example, if an eye opener is designed to retime a data stream of about 10 Gb/s, the bypass control 377 may automatically pass-through a 1 Gb/s data stream. Alternatively, the bypass control 377 may be manually controlled allowing a host 105 or network operator to determine whether to pass-through a particular data stream. A loopback control 387 allows the eye opener control module 350 to monitor the integrity of data paths and components on module 200. The BERT control 389 allows the eye opener control module 350 to test bit error rates of data paths and components on module 200. In other embodiments, additional controls to chip functions may be added to the eye opener control 350 such as an adaptive equalizer control.
In one embodiment, a serial interface 385 allows a serial connection 390 to communicate with the eye opener control module 350. In general, a serial connection such as SPI, I2C, RS232, etc. may be used to control functions of the dual eye opener integrated circuit 300. Other embodiments of serial connections are disclosed in U.S. patent application Ser. No. 10/266,870, “Optical Transceiver Module with Multipurpose Internal Serial Bus,” by Lewis B. Aronson et al, filed Oct. 8, 2002, which is incorporated by reference herein. Accordingly, the number of pins required to command the eye opener control module 350 is reduced to a single pin. For example, this serial interface 385 replaces four pins in a four rate configuration or two pins in a binary rate configuration. In yet another embodiment, a second serial interface (not pictured) may provide output to the host such as current polarity setting, a LOL signal, current baudrate, a current clocking frequency, loopback test results, or BERT results. Alternatively, the serial connection may be a single serial interface capable of facilitating two-way communication between the eye opener control module 350 and the host.
The not ready signal output to the host from an output of a control logic 999b is conditioned upon receiving a LOS signal from an output of buffer 945d or a LOL signal from an output of the CDR 925b. The MUX 955d provides bypass functionality. Bypass functionality is activated with a signal from the output of control logic 999b to a selector input of the MUX 955d. In another embodiment the Tx clock functionality may be implemented in the eye opener 205a.
The above-described loopback modes are examples of loopbacks that may be integrated in the transceiver module 200 and is not meant to include all possible loopback modes. For example, loopbacks may be integrated from the input 412 of the receiver eye opener 205b to both the input 407 and the output 417 of the transmitter eye opener 205a. These loopbacks would allow testing of the front end components and an optical path as well a combination of front end components, the receiver eye opener 205a and an optical path. Additional loopbacks may also be integrated within the transceiver module 200 to test other data paths and/or components.
Referring to the example of
In eye opener 205b, MUXs 955e and 955f receive a second loopback signal from the host to each selector input. When the second loopback signal is high, the output of MUX 955f sends data received from the CDR 925a to the input of RT 935b rather than data from CDR 925b, and a recovered clock signal received from the CDR 925a to the input of RT 935b rather than from the CDR 925a.
In an alternative embodiment of the third loopback mode, the buffer 945a may be isolated by coupling the output of the buffer 945a to the output of the buffer 945e as in the first loopback mode. It will be understood that each of the other loopback modes may be similarly implemented. The second loopback mode may be implemented by coupling the input of the first CDR 925a or the input of the first buffer 945a to the output of the second CDR 925b or the input of the buffer 945a. The fourth loopback mode may be implemented by coupling the output of the second CDR 925b to the input of the first CDR 925b. The fifth loopback mode may be implemented by coupling the output of the second CDR 925b to the output of the first CDR 925a. The above-described loopback implementations are examples that are not meant to include all possible implementations.
The bypass functionality of the present invention allows an eye opener to automatically pass data through if it is unable to lock onto the data because it is not in a particular data rate band. In particular, the eye opener may be designed to pass-through a data stream having a data rate such that clock and data recovery is not required to remain within an acceptable jitter budget. For example, this pass-through functionality would allow a 10 Gb/s Ethernet transceiver to operate in particular Fibre Channel environments where a eye opener is not required. Additionally, the functionality allows debugging or engineering of a link to occur without the presence of the non-linear regeneration feature of the eye opener. The pass-through functionality of the eye opener may be automatically controlled depending on whether the eye opener is locked to the data. The eye opener may generate a LOL signal which is a signal of general use, but which can also be used for this purpose. The pass-through functionality may also be externally controlled by a control signal or by a digital signal on a digital interface. It is recognized that the bypass feature is valuable as a diagnostic and development tool even for data rates that are within the locking range of the eye opener.
One embodiment of a transceiver module 200 having pass-through functionality, shown in
A similar bypass operation may be provided on the transmitter eye opener 205a. In particular, a first buffer 945a is coupled to a first CDR 925a and a pass-through line 526. The pass-through control 510 toggles data between the first CDR 925a and the pass-through line 526 depending on the characteristics of the data. Additionally, multiple eye openers (e.g., a third CDR 925c) may operate within the transmitter eye opener 205a to facilitate different data streams being provided eye opener functionality on the eye opener 205b.
In one embodiment, adaptive equalization is performed on signal by the host board during bypass mode for noise reduction and/or signal processing. The not ready signal may be polled to determine whether the eye opener is currently operating in bypass mode, initiating the adaptive equalization functionality when the not ready signal is high. The adaptive equalization feature advantageously compensates for link dispersion as a substitute for retiming and reshaping ordinarily provided by the eye opener.
The BERT engine eye opener uses test points integrated within the data paths to inject and receive bit sequences that are used to test the bit error rate associated with particular paths. In this example, four test points are integrated on the transceiver module 200 and are identified as points A 605, B 610, C 615, and D 620. These test points 606, 610, 615, 620 allow the BERT engine 630 to inject and retrieve bit sequences on a data path. Using these test points, the BERT engine 630 may determine a bit error rate on external optical paths on an attached network, internal electrical paths or a combination of both electrical and optical paths.
The BERT engine 630 is useful both as a diagnostic function for end-customers in their systems, but is also useful as part of the module manufacturing process. For example, a manufacturer may perform integrity tests on the transceiver module 200 to ensure that the module passes a quality test. The BERT engine 630 may test internal paths on the module 200 during various operating conditions such as operating within a temperature chamber under temperature cycle or voltage margining. This feature provides a more efficient method of testing the module 200 when compared to more traditional external BERTs. Additionally, both the loopback modes and BERT engine 630 may operate in transponder modules as well.
The equalizer 2120 resets the data path's jitter budget by reshaping and retiming the data to remove channel noise from sources such as inter-symbol interference. The equalizer 2120 is coupled to receive signals representing coefficients from a coefficient module 2110 and a clock signal from a CDR 2130. The equalizer 2120 is preferably an adaptive equalizer that adapts to channel conditions such as changing temperature, but in other embodiments, the equalizer 2120 may be a passive equalizer. Other embodiments of equalizers are disclosed in U.S. patent application Ser. No. 10/288,324, “System and Method for Reducing Interference in an Optical Data Stream,” by Thomas J. Lenosky et al., filed on Nov. 5, 2002; U.S. Patent Application No. 60/423,970, “System and Method for Reducing Interference in an Optical Data Stream Using Multiple Selectable Equalizers,” by Thomas J. Lenosky et al, filed on Nov. 5, 2002; and U.S. patent application Ser. No. 10/419,023, “Method And Apparatus For Reducing Interference in an Optical Data Stream Using Data-Independent Equalization,” by Thomas J. Lenosky et al., filed on Apr. 17, 2003; all of which are herein incorporated by reference. The equalizer 2120 may comprise a feed forward filter having a finite impulse response, a DFE (“Decision Feedback Equalizer”), or the like, either alone or in combination. The output of the equalizer 2120 may be analog or digital, depending on the implementation. Further embodiments of the equalizer 2120 are discussed below.
The coefficient module 2110 provides coefficients to the equalizer 2120 by evaluating channel effects on the data. The coefficient module 2110 is coupled to receive the data from the buffer 2105a and send the coefficient signal to the equalizer 2120. The coefficient module 2110 may be implemented in hardware, software, or firmware. Further embodiments of the coefficient module 2110 are discussed below.
The CDR 2130 provides a clock to the equalizer 2120 by extracting a recovered clock signal from the data stream. The CDR 2130 is coupled to receive the data from the buffer 2105a and to send a clock signal to the equalizer 2120. One of ordinary skill in the art will recognize that the CDR 2130 may receive the data to recover the clock signal from other points in the data path such as at the equalizer 2120 output. Furthermore, the CDR 2130 may comprise the variations discussed herein.
In contrast to the embodiment of
The CDR 2160 and RT 2170 retime and reshape the equalized data. The RT 2170 receives a clock signal recovered by the CDR 2160. The CDR 2160 and RT 2170 may comprise the variations discussed herein.
In another embodiment, the equalizer 2150 is disposed on a first chip and the CDR 2160 and RT 2170 are disposed on a second chip. The first chip may also comprise a CDR to clock the digital portions of the equalizer 2150 without relying on the CDR 2160 of the second chip. Advantageously, by not traveling off-chip, the high-speed clock signal may remain low-powered and experience less degradation.
The delay lines 2210a-c, 2220a,b delay the data stream so that data bits are input at individual integrators at different clock cycles. The delay lines 2210a-c, 2220a,b are coupled to receive an analog signal carrying either analog or digital data and send the data to the multipliers 2230a-c, 2240a,b. The delay lines 2210a-c, 2220a,b maybe implemented in various ways such as through analog transmission lines comprising combinations of inductors and capacitors. Preferably, the delay is a one-bit period.
The multipliers 2230a-c, 2240a,b generate a product of the data and coefficients. The multipliers 2230a-c, 2240a,b are coupled to receive the data signals and the coefficient signals and send to send a signal to the summer 2250. The summer 2250 generates a sum of the feed forward filter and the DFE. The summer 2250 is coupled to receive signals from the feed forward multipliers 2230a-c and from the DFE multipliers 2240a,b. The slicer 2260 receives the analog signal from the summer 2250 and a clock signal, and generates a digital output according to the clock signal.
In one embodiment, the equalizer 2200 outputs a digital signal from the slicer 2260 output such as in the embodiment of
The bank of correlation 2810a-c modules performs autocorrelation functions on the data stream. The bank of correlation modules 2810a-c receive data signals from the input buffer and send signals to the ADC logic 2820. In
The ADC logic 2820 digitizes analog signals from the bank of correlation modules 2810a-c and sends digital signals to the microcontroller 2830. The ADC logic 2820 comprises a multiplexor to multiplex multiple inputs on a single output. The microcontroller 2830 uses algorithms to determine coefficient values according to the autocorrelation results. The microcontroller 2830 comprises a memory element such as a EEPROM for storing instructions and past coefficient values. The DAC logic 2840 generates an analog signal from the digitized output of the micro controller 2830.
The correlation module 2900 is configured to calculate an autocorrelation function of the signal at different times, i.e., <s(t)s(t+δ)>. A first data path includes a multiplier 2920a that receives inputs directly from the data stream and after a delay line 2910a and sends an output signal to an integrator 2930a. A second data path includes a multiplier 2920b that receives inputs directly from the data stream and after two delay lines 2910a,b and sends an output signal to an integrator 2930b. A third data path includes a multiplier 2920c that receives inputs directly from the data stream and after three delay lines 2910a-c and sends an output signal to an integrator 2930c. The number and types of data paths may vary according to specific implementations within the scope of the present invention. The products are sent to a microcontroller.
The combinations of dual eye openers integrated with post amp and laser driver either singly or in combination may also be accomplished in the case of single eye openers 205a, b. Eye opener 205b can be integrated with the postamp or may have sufficient input sensitivity to eliminate the requirement for a post amp. The eye opener 205b may also have signal detect features or other functions that may be incorporated into a post amp or used in a receiver. Likewise, the eye opener 205a may be integrated with the laser driver and with any other circuitry that is used in a transmitter, for example laser bias control circuitry. Eye opener 205a may have provisions for adjustable output swing, adjustable edge speed of the output, and other features that may be incorporated into laser drivers.
In one embodiment, a component may operate on a duty cycle. For example, the circuitry necessary for the LOS may be powered up in response to a polling of the CDR. If the LOS condition exists, then the LOS signal is output. However, if the LOS condition does not exist, then a power savings is realized since the LOS will not be powered up again until the next polling.
A power management module 805 within the eye opener control module 350 dynamically controls power levels on various components on the eye opener integrated circuit 800. For example, the power management module 805 may shut down the BERT engine 630 or pass-through control 510 if they are not being used. Additionally, the power management module 805 may decrease power to a eye opener (e.g., the receiver eye opener 205b or transmitter eye opener 205a) if it is not operating and may restore power to the eye opener when needed.
In one embodiment, a host startup protocol module 810 within the eye opener control module 350 dynamically controls power levels on components during installation. For example, the host startup protocol module 810 may facilitate an initial handshaking procedure between the transceiver module 200 and the host 105. During installation, the transceiver module 200 may transmit a low power level inquiry to the host to request a start-up procedure. In response, the host 105 replies to the inquiry and the host startup protocol module 810 then powers up components on the transceiver module 200 needed to complete the setup procedure. Additionally the host 105 may communicate data describing whether its protocol operation of the dual eye openers.
The power management module 805 and host startup protocol module 810 allow components on the transceiver module 200 to operate in a sleep mode when not in use. As a result, power management efficiency is increased and heat on the chip is reduced.
As is evident from the preceding discussion, the invention may be implemented in a variety of different embodiments. It was noted above, for example, in connection with the discussion of the exemplary embodiment disclosed in
One such data rate that is of interest is an 8 Gb/s data rate used in many protocols. Another such data rate is the 8.5 Gb/s data rate employed in Fibre Channel systems, although the scope of the invention is not, however, limited to use in connection with Fibre Channel systems and extends more broadly to a variety of other environments and data rates as well. More particularly, an embodiment of the invention concerns a 10 G XFP transceiver that is configured to operate at 8.5 Gb/s with CDR bypass. This general configuration may be employed in Fibre Channel, or other, systems and applications that use an 8.5 Gb/s data rate. Note that this exemplary 8.5 Gb/s data rate associated with the Fibre Channel protocol may also be referred to as generally corresponding with an 8.0 Gb/s data rate associated with various other protocols.
Directing attention now to
In general, the XFP transceiver 3000 can be used at data rates different than typical 10 Gb/s applications, such as 8.5 Gb/s, as a result of a CDR bypass feature of the XFP transceiver 3000 which allows the high-speed data stream to bypass the CDR unit and be output directly. With regard to the aforementioned figures,
As collectively disclosed by the
Particularly, the controller IC 3002 communicates with a laser driver 3006, disclosed in
With attention now to particular aspects of the exemplary XFP transceiver, details are provided concerning an implementation of the CDR bypass functionality at the 8.5 Gb/s data rate. In particular, a bit in the XFP transceiver user EEPROM table (not shown) is set to enable or disable the CDR bypass function. The bit can be preset by manufacture and can also be set/reset by a programmer or user through the XFP a transceiver 2-wire serial communication interface in the XFP connector 3004.
When the XFP transceiver detects the bit change to “enable” at this location, the controller IC(U12) sends a signal to the Rx_bypass pin 11 of the post-amplifier/CDR 3016 (see
As disclosed elsewhere herein, the bypass can be performed automatically in response to detection of the data rate, or can be performed manually by a user so that the user can select specific signals to bypass the CDR. Additionally, bypass can be performed for a predetermined range of data rates, or for each data rate in a selected group of different data rates.
Referring back now to the illustrated embodiment, when CDR bypass is invoked, the host 8.5 Gb/s electrical data passes through the XFP transceiver and the electrical/optical front end, or TOSA 3010 (see
Turning now to
With reference first to the Tx optical eye diagrams for 8.5 Gb/s at room temperature,
The electrical performance of the 10 G XFP transceiver using an 8.5 Gb/s CDR bypass is favorable as well. Among other things,
Finally,
Thus,
The present invention provides several benefits over conventional transceiver modules. A first benefit is that is may be used to improve the performance of XFP transceiver modules. XFP transceiver modules are small form factor optical modules operating at a data rate of approximately 10 Gb/s.
Another benefit of the present invention is that the transceiver module may be plugged into serial connectors on a host reducing the number of SERDES components on both the host and transceiver module. Dual eye openers may be placed in the transmit and receive paths to ensure that data streams remain within a predefined jitter budget. The removal of SERDES components decreases the amount of heat on the transceiver chip(s), decreases the component cost, and reduces the required area on a chip substrate for components.
An additional benefit of the present invention is that particular functionalities may be integrated on the transceiver module. A first functionality is providing control of various components, including dual eye openers, via a serial connection. This serial connection reduces the number of pins and connections required to control the transceiver module. A second functionality is providing multiple loopback modes that may be used to test components and data paths on both the transceiver module and optical paths on an attached network. Furthermore, a BERT engine may be integrated on the module to further enhance this testing and monitoring capability of the loopback modes. These functionalities lower the manufacturing costs and installation costs because the internal testing described above provides more efficient and cost effective methods of testing than conventional testing procedures.
Still yet another benefit of the present invention is that a pass-through functionality may be integrated on the transceiver module. This pass-through function allows the transceiver module to operate in different networking environments having different data rates and eye opener requirements.
The present invention may also include power management functionality that is integrated on the transceiver module. This power management function allows the dynamic control of power to components on the module during both operation and installation. As a result, power is conserved and heat reduced on the chips.
While the present invention has been described in detail in regards to a transceiver, it will be understood from the above description that embodiments of the present invention may be applied to a transponder as well. Additionally, while the present invention has been described with reference to certain exemplary embodiments, those skilled in the art will recognize that various modifications may be provided. For example, other types of circuits may be used to reduce jitter or open an eye diagram at a transceiver or transponder module. For example, both passive and adaptive equalization circuits may be used for these purposes. Also, one skilled in the art will recognize that the above description may apply to reclocking circuitry as well. Accordingly, the functionalities described above are not meant to be limited to an eye opener, but may be used in a number of circuits used to improve a signal such as signal conditioners or eye openers.
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
This application is a continuation-in-part (CIP), and claims the benefit, of U.S. patent application Ser. No. 10/420,027, entitled TRANSCEIVER MODULE AND INTEGRATED CIRCUIT WITH DUAL EYE OPENERS, filed Apr. 17, 2003 now U.S. Pat. No. 7,486,894 which, in turn, claims the benefit of: U.S. Provisional Patent Application Ser. No. 60/410,509, filed Sep. 13, 2002; and U.S. Provisional Patent Application Ser. No. 60/391,877, filed Jun. 25, 2002. All of the foregoing patent applications are incorporated herein in their respective entireties by this reference.
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