Patent Abstract:
A fiber optic receiver that includes an opto-electronic transducer, an adjustable response preamplifier circuit, and a post-amplifier circuit is described. The opto-electronic transducer is configured to generate an electrical data signal in response to a received optical data signal. The adjustable response preamplifier circuit is coupled to the opto-electronic transducer and is operable to amplify an electrical data signal generated by the opto-electronic transducer. The post-amplifier circuit is coupled to an output of the preamplifier circuit and is configured to transmit a mode control signal to the preamplifier circuit in response to a received control signal. By transmitting the mode control signal from the post-amplifier to the preamplifier, the adjustable response amplifier may be placed in the preamplifier stage within a receiver optical sub-assembly (ROSA). As a result, the fiber optic receiver may accommodate multiple operating modes (e.g., multiple bandwidth and power operating modes) while conforming to existing receiver optical sub-assembly (ROSA) size and pin count constraints.

Full Description:
TECHNICAL FIELD 
     This invention relates to fiber optic receivers and wideband receiver amplifiers subject to relatively tight packaging constraints. 
     BACKGROUND 
     Many advanced communication systems transmit information through a plurality of parallel optical communication channels. The optical communication channels may be defined by a fiber optic ribbon interconnect (or fiber optic cable) formed from a bundle of glass or plastic fibers, each of which is capable of transmitting data independently of the other fibers. Relative to metal wire interconnects, optical fibers have a much greater response, they are less susceptible to interference, and they are much thinner and lighter. Because of these advantageous physical and data transmission properties, efforts have been made to integrate fiber optics into computer system designs. For example, in a local area network, fiber optics may be used to connect a plurality of local computers to centralized equipment, such as servers and printers. In this arrangement, each local computer has an optical transceiver for transmitting and receiving optical information. The optical transceiver may be mounted on a substrate that supports one or more integrated circuits. Typically, each computer includes several substrates that are plugged into the sockets of a common backplane. The backplane may be active (i.e., it includes logic circuitry for performing computing functions) or it may be passive (i.e., it does not contain any logic circuitry). An external network fiber optic cable may be connected to the optical transceiver through a fiber optic connector that is coupled to the backplane. 
     Fiber optic transceivers typically include a transmitter component and a receiver component. The transmitter component typically includes a laser, a lens assembly, and a circuit for driving the laser. The fiber optic receiver component typically includes a photodiode and a high gain receiver amplifier, which may be operable to perform one or more signal processing functions (e.g., automatic gain control, background current canceling, filtering or demodulation). For one-directional data transfer, a transmitter component is required at the originating end and a receiver component is required at the answering end. For bi-directional communication, a receiver component and a transmitter component are required at both the originating end and the answering end. In some cases, the transmitter circuitry and the receiver circuitry are implemented in a single transceiver integrated circuit (IC). The transceiver IC, photodiode and laser, along with the lenses for the photodiode and the laser are contained within a package that has a size that is sufficiently small to fit within a fiber optic communication device. 
     SUMMARY 
     In one aspect, the invention features a fiber optic receiver that includes an opto-electronic transducer, an adjustable response preamplifier circuit, and a mode selection circuit. The opto-electronic transducer is configured to generate an electrical data signal in response to a received optical data signal. The adjustable response preamplifier circuit is coupled to the opto-electronic transducer and is operable to amplify an electrical data signal generated by the opto-electronic transducer. The mode selection circuit is coupled to an output of the preamplifier circuit and is configured to transmit a mode control signal to the preamplifier circuit in response to a received control signal. 
     Embodiments of the invention may include one or more of the following features. 
     The mode selection circuit may be configured to transmit the mode control signal to the preamplifier circuit in response to a received data rate control signal or a received power mode control signal. 
     The mode selection circuit preferably is configured to modulate the mode control signal onto a common line coupled between the preamplifier circuit and the post-amplifier circuit. The mode selection circuit may be configured to modulate the mode control signal onto the common line as a single pulse or as a multiple pulse pattern. In some embodiments, the mode selection circuit is configured to modulate the mode control signal onto the common line as a time-varying signal. 
     The preamplifier circuit preferably comprises a mode detection circuit that is configured to generate a response control signal for adjusting the response of the preamplifier circuit based upon the mode control signal transmitted by the mode selection circuit. 
     In some embodiments, the mode detection circuit is configured to detect one or more mode control signal pulses modulated onto a common line coupled between the preamplifier circuit and the mode selection circuit. In these embodiments, the mode detection circuit may be configured to detect the one or more mode control signal pulses based upon a comparison of a common line voltage with a reference voltage. 
     In other embodiments, the mode detection circuit is configured to detect a time-varying mode control signal modulated onto a common line coupled between the preamplifier circuit and the mode selection circuit. In these embodiments, the mode detection circuit preferably comprises a frequency detector. 
     The preamplifier circuit may be configured to select one of multiple sets of operating parameters based upon the mode control signal transmitted by the mode selection circuit. For example, the preamplifier circuit may be configured to adjust one or more bandwidth response parameters in response to a bandwidth mode control signal transmitted by the mode selection circuit. Alternatively, the preamplifier circuit may be configured to adjust one or more supply current operating parameters in response to a power mode control signal transmitted by the mode selection circuit. 
     The mode selection circuit preferably is incorporated within a post-amplifier circuit. 
     In some embodiments, the fiber optic receiver may include a receiver optical sub-assembly (ROSA) comprising a fiber optic connector for coupling to a mating connector of a fiber optic cable. The preamplifier circuit may be incorporated within the ROSA. The ROSA and the post-amplifier circuit may be mounted on a common substrate. 
     Among the advantages of the invention are the following. 
     By transmitting the mode control signal from the mode selection circuit to the preamplifier, the adjustable response amplifier may be placed in the preamplifier stage within a receiver optical sub-assembly (ROSA). As a result, the fiber optic receiver may accommodate multiple operating modes (e.g., multiple bandwidth and power modes) while conforming to existing receiver optical sub-assembly (ROSA) size and pin count constraints. This feature enables the analog electrical data signals generated by the opto-electronic transducer to be amplified, filtered, and shaped optimally for data recovery, while allowing the receiver to be housed within a package sized to fit within fiber optic communication devices with significant size constraints. 
     Other features and advantages of the invention will become apparent from the following description, including the drawings and the claims. 
    
    
     
       DESCRIPTION OF DRAWINGS 
         FIG. 1  is a diagrammatic view of a fiber optic receiver, which includes an opto-electronic transducer, a preamplifier circuit and a post-amplifier circuit, and a fiber optic cable carrying an optical data signal to the fiber optic receiver. 
         FIG. 2A  is a diagrammatic cross-sectional side view of a fiber optic cable coupled by a pair of mating connectors to a receiver optical sub-assembly (ROSA) of the fiber optic receiver of FIG.  1 . 
         FIG. 2B  is a diagrammatic cross-sectional end view of a header module of the ROSA of  FIG. 2A  taken along the line  2 B— 2 B. 
         FIG. 3  is a circuit diagram of the fiber optic receiver of FIG.  1 . 
         FIG. 4  is a circuit diagram of a post-amplifier mode selection circuit. 
         FIG. 5A  is a diagrammatic view of a data rate control signal, a positive edge-triggered one-shot output signal, and a negative edge-triggered one-shot output signal, each plotted as a function of time. 
         FIG. 5B  is a graph of voltage values on the data lines of the fiber optic receiver of  FIG. 1  plotted as a function of time. 
         FIG. 6  is a circuit diagram of a preamplifier mode detection circuit. 
         FIG. 7  is a circuit diagram of an alternative post-amplifier mode selection circuit. 
     
    
    
     DETAILED DESCRIPTION 
     In the following description, like reference numbers are used to identify like elements. Furthermore, the drawings are intended to illustrate major features of exemplary embodiments in a diagrammatic manner. The drawings are not intended to depict every feature of actual embodiments nor relative dimensions of the depicted elements, and are not drawn to scale. 
     Referring to  FIG. 1 , in one embodiment, a fiber optic receiver  10  includes an opto-electronic transducer  12  (e.g., a p-i-n photodiode), an adjustable response preamplifier circuit  14 , and a post-amplifier circuit  16 . In operation, a fiber optic cable  18  carries an optical data signal  20  to opto-electronic transducer  12 . In response to optical data signal  20 , opto-electronic transducer  12  generates an electrical data signal  22 , which is amplified by preamplifier circuit  14 . Preamplifier circuit  14  is configured to amplify electrical data signal  22  over a prescribed range of optical power for optical data signal  20 . The resulting pre-amplified electrical data signal  24  is further amplified by post-amplifier circuit  16 , which amplifies and shapes electrical data signal  24  so that data embedded in output signal  26  may be extracted by a conventional clock and data recovery circuit. 
     As explained in detail below, preamplifier circuit  14  has an adjustable response that may be set by a control signal  28  (e.g., a data rate control signal or a power mode control signal) that is received by post-amplifier circuit  16 . Post-amplifier circuit  16  transmits a corresponding mode control signal to preamplifier circuit  14  to optimize the performance of fiber optic receiver  10  for different operating conditions. For example, in one embodiment, when the data rate of the received optical data signal  20  is high, the cutoff frequency of preamplifier  14  may be set high (e.g., about 1.5 GHz to about 2.5 GHz), whereas when the data rate is low, the cutoff frequency of preamplifier circuit  14  may be set low (e.g., about 0.5 GHz to about 1.5 GHz). In this embodiment, the data rate of optical data signal  20  may be known a priori or may be extracted by a phase-locked loop or other techniques in the clock and data recovery circuit or in the post-amplifier circuit  16 . In some embodiments, both preamplifier circuit  14  and post-amplifier circuit  16  have adjustable responses. 
     As shown in  FIG. 2A , in one embodiment, fiber optic cable  18  includes a cable connector  30  that couples to a mating receiver connector  32  of fiber optic receiver  10 . Cable connector  30  includes a socket  34  that is configured to slide over a protruding lip  36  of receiver connector  32 . An annular sleeve  38  is disposed about the distal end of fiber optic cable  18  and is configured to slide within a channel  40  defined within receiver connector  32 . Socket  34  has a pair of pins  42 ,  44  that are slidable within vertical slots  46 ,  48  of lip  36 . Socket  34  may be slid over lip  36 , with pins  42 ,  44  aligned with slots  46 ,  48 , until pins  42 ,  44  reach the ends of slots  46 ,  48 . Socket  34  then may be rotated to seat pins  42 ,  44  in end extensions  50 ,  52  of slots  46 ,  48 . The process of seating pins  42 ,  44  within end extensions  50 ,  52  compresses a biasing mechanism  54  (e.g., a rubber o-ring) that urges socket  34  against receiver connector  32 , effectively locking cable connector  30  to receiver connector  32 . When properly seated within channel  40 , the one or more fibers of fiber optic cable  18  are aligned with a lens assembly  56 , which focuses optical data signals  20  onto opto-electronic transducer  12 . 
     Referring to  FIG. 2B , opto-electronic transducer  12  and preamplifier circuit  14  are housed within a header module  58  of a receiver optical sub-assembly (ROSA)  60 , which is mounted on a substrate  62  (e.g., a printed circuit board or other support for passive and active components) of fiber optic receiver  10 . ROSA  60  and substrate  62  are contained within a receiver package  63 . Opto-electronic transducer  12  is mounted centrally within ROSA  60  to receive optical data signals that are carried by fiber optic cable  18  and focused by lens  56 . ROSA  60  also includes a plurality of insulated posts  64 ,  66 ,  68 , which define channels through which electrical connectors extend to couple substrate  62  to opto-electronic transducer  12  and preamplifier circuit  14 . 
     Other embodiments may use fiber optic connectors that are different from the bayonet-type connectors  30 ,  32  to couple fiber optic cable  18  to receiver  10 . Receiver  10  may be housed within a standalone receiver package or may be housed together with a transmitter component in a transceiver package. 
     Referring to  FIG. 3 , in one embodiment, preamplifier circuit  14  includes an adjustable response high gain amplifier  70  and a mode detection circuit  72 . Post-amplifier circuit  16  includes a high gain amplifier  74  and a mode selection circuit  76 . In some embodiments, mode selection circuit  76  may be implemented as a circuit that is separate from post-amplifier circuit  16 . In response to a received control signal  28 , mode selection circuit  76  generates a mode control signal, which is transmitted to preamplifier circuit  14 . In one embodiment, mode selection circuit  76  is configured to transmit the mode control signal over data lines  78 ,  80  (i.e., data, data-bar). In another embodiment, mode selection circuit  76  is configured to transmit the mode control signal to preamplifier circuit  14  over a power line that is coupled between preamplifier circuit  14  and post-amplifier circuit  16 . In general, mode selection circuit  76  may be configured to transmit the mode control signal to preamplifier circuit  14  over one or more common lines that are coupled between preamplifier circuit  14  and post-amplifier circuit  16 . Mode detection circuit  72  is configured to detect the mode control signal that is transmitted by mode selection circuit  76  and to generate a response control signal  82  for adjusting the response (or signal processing characteristics) of amplifier  70 , including the bandwidth, gain, noise, and time response of amplifier  70 . Bias levels and passive element values (e.g., resistance, capacitance and conductance values) may be varied, as well as other techniques, to achieve a desired frequency and time domain characteristic behavior of amplifier  70 . 
     The response of amplifier  70  may be adjusted in different ways. 
     For example, the bandwidth response may be adjusted by varying the bias conditions of a variable transconductance transistor in the preamplifier circuit. Alternatively, the bandwidth response may be adjusted by varying the bias voltage applied to a varactor (voltage-variable capacitor) in the preamplifier circuit. The bandwidth response also may be adjusted by varying capacitance values or resistance values in low-pass filters coupled to the signal paths through the preamplifier circuit. The bandwidth response alternatively may be adjusted by varying the gain of an amplifier within preamplifier circuit  14 . 
     In some embodiments, the operating power parameters of amplifier  70  may be adjusted based upon response control signal  82 . For example, control signal  28  may correspond to a power mode signal (e.g., a power-up mode signal, power-down mode signal, or sleep or standby mode signal). In this case, mode selection circuit  76  transmits a power mode control signal to mode detection circuit  72 . In response, mode detection circuit  72  generates a power response control signal  82  that is configured to set the operating power mode of amplifier  70 . 
     Amplifier  70  may have a continuously variable response or a discrete variation in response. A continuously variable amplifier response may be achieved by incrementing or decrementing the amplifier characteristics based upon each pulse detection. Similar results may be achieved by counting each time a frequency is detected. The amplifier response also may be varied based upon pulse amplitude modulation or the actual frequency of the mode control signal. 
     Referring to  FIG. 4 , in one embodiment, mode selection circuit  76  is configured to transmit the mode control signal as a single pulse modulation over data lines  78 ,  80 . In this embodiment, mode selection circuit  76  includes a positive edge-triggered one-shot  84 , a negative edge-triggered one-shot  86  and a pair of pull down switches  88 ,  90 , which are configured to selectively pull the voltages on data lines  78 ,  80  close to ground potential. Positive edge-triggered one-shot  84  and negative edge-triggered one-shot  86  may be implemented in a conventional way (e.g., with NAND gates and inverters). Pull down switches  88 ,  90  may be implemented by conventional transistors that are large enough to pull down the voltages on data lines  78 ,  80  substantially below the reference voltage (e.g., close to ground potential). 
     As shown in  5 A and  5 B, in operation, control signal  28  may have a low value for a first mode of operation (Mode  1 ) that may correspond to a low data rate (or a first power mode), and a high value for a second mode of operation (Mode  2 ) that may correspond to a high data rate (or a second power mode). When the value of control signal  28  switches from low to high, positive edge-triggered one-shot  84  generates a pulse  92  that closes switch  88 , which pulls down data line  78  close to ground potential (V Gnd ). When the value of control signal  28  switches from high to low, negative edge-triggered one-shot  86  generates a pulse  94  that closes switch  90 , which pulls down data-bar line  80  close to ground potential (V Gnd ). 
     Referring to  FIG. 6 , in one embodiment, preamplifier mode detection circuit  72  is configured to detect the single pulse modulations on data line  78  and data-bar line  80  based upon a comparison of the data line voltages with a reference voltage (V Ref ). The reference voltage has a value between ground potential and the normal operating range of electrical data signals  24  (e.g., V cc −0.5 volts to V cc −0.25 volts, where V cc  corresponds to the positive supply voltage). Mode detection circuit  72  includes a pair of comparators  96 ,  98  that have negative inputs coupled to the reference voltage and positive inputs coupled to data lines  78 ,  80 , respectively. The outputs of comparators  96 ,  98  are coupled through a pair of inverters  102 ,  104  to the set (S) and reset (R) inputs of an SR latch  100 , respectively. In operation, the outputs of comparators  96 ,  98  are low only when data lines  78 ,  80  are pulled below the reference voltage. Accordingly, when data line  78  is pulled below V Ref , SR latch  100  is set to a value of 1. When data-bar line  80  is pulled below V Ref , on the other hand, SR latch  100  is set to a value of 0. In this way, the operating condition information contained in control signal  28  may be transmitted from post-amplifier circuit  16  to preamplifier circuit  14  in the form of a single pulse modulation on data line  78  or data-bar line  80 , or both. The response of amplifier  70  may be adjusted in one or more of the ways described above based upon the response control signal  82  produced at the output of SR latch  100 . 
     Other embodiments are within the scope of the claims. 
     For example, in some embodiments, mode selection circuit  76  may be configured to modulate the mode control signal onto one or more common lines coupled between preamplifier circuit  14  and post-amplifier circuit  16  as a multiple pulse pattern, rather than as a single pulse. In these embodiments, mode detection circuit  72  may include a decoder or other circuit configured to generate an appropriate response control signal  82  corresponding to the response mode specified by the multiple pulse mode control signal pattern. 
     In other embodiments, mode selection circuit  76  may be configured to modulate the mode control signal onto one or more common lines that are coupled between preamplifier circuit  14  and post-amplifier circuit  16  as a time-varying signal. For example, referring to  FIG. 7 , in one embodiment, mode selection circuit  76  may include a pair of frequency controllers  110 ,  112 , each of which is coupled to a respective adjustable frequency voltage source  114 ,  116 . Voltage sources  114 ,  116  are selectively coupled to data lines  78 ,  80  by a pair of switches  118 ,  120  and are configured to modulate a time varying mode control signal onto the data signals carried by lines  78 ,  80 . In operation, frequency controllers  110 ,  112  set the frequency of voltage sources  114 ,  116  based upon the value (or state) of control signal  28 . The frequencies set by frequency controllers  110 ,  112  may be the same or different. In accordance with this embodiment, a large number of different response modes may be selected to accommodate a corresponding number of different operating conditions. For example, four different response modes may be established by selectively setting each of voltage sources  114 ,  116  to have one of two different frequencies (f 1 , f 2 ), as illustrated in Table 1 below. 
                                                   TABLE 1               Data Rate Control   Data Line 78   Data Line 80           Signal State   Frequency   Frequency   Response Mode                                1   f 1      f 1     R 1         2   f 2     f 1     R 2         3   f 1     f 2     R 3         4   f 2     f 2     R 4                      
In this embodiment, mode detection circuit  72  preferably includes a pair of frequency detectors that are configured to resolve the frequencies of the time-varying mode control signals modulated onto data lines  78 ,  80 .
 
     In some embodiments, mode selection circuit  76  may be configured to modulate the mode control signal onto one or more common lines that are coupled between preamplifier circuit  14  and post-amplifier circuit  16  as an amplitude modulated signal. In these embodiments, mode selection circuit  76  may include a pair of frequency sources that are capable of producing amplitude modulated output signals. Mode detection circuit  72  preferably includes a corresponding pair of amplitude demodulators that are configured to resolve the amplitude variations modulated onto the mode control signals transmitted by mode selection circuit  76 . 
     Still other embodiments are within the scope of the claims.

Technology Classification (CPC): 7