US20040022537A1

US20040022537A1 - Laser communication system

Info

Publication number: US20040022537A1
Application number: US10/630,449
Authority: US
Inventors: George Mecherle; Terry Holcomb; Robert Carlson; Fang-Xin Wang; Vladimir Draganov
Original assignee: FSONA Communications Corp
Current assignee: FSONA Communications Corp; Olympus Corp
Priority date: 2001-01-24
Filing date: 2003-07-29
Publication date: 2004-02-05
Also published as: WO2002060074A3; EP1358727A2; WO2002060074A2; AU2002242073A1; US20040031272A1; KR20030078890A; CA2436190A1; US6978624B2; US20020097468A1; TW550891B

Abstract

An optical wireless transceiver for communicating broadband signals through free space includes an input, a regenerator, a splitter and a plurality of lasers in transmitter modules. A very fast (low f-number) optical receiver module includes a reflector aligned with an input aperture. A photodiode receives the signal from the reflector for subsequent demodulation. A background rejection filter is disposed between the reflector and the photodiode at the focal point of the mirror. The transceiver provides signal regeneration and switchable data rates. Connections are made to optical or electrical digital inputs and outputs bearing signals of various protocols. The plurality of lasers includes adjustable-beamwidth collimating lenses. An efficient high-current, high power laser driver capable of modulating a laser between 100 and 1500 mA at data rates greater than 10 Mbits/sec is provided. A highly efficient thermoelectric cooler operates to cool the laser diode, or other components requiring cooling.

Description

PRIORITY

This is a divisional U.S. patent application Ser. No. 09/769,082, filed Jan. 24, 2001, the disclosure of which is incorporated herein by reference, to which priority under 35 U.S.C. § 120 is claimed.[0001]

BACKGROUND

1. Field of the Invention

The field of the present invention is laser communications.

2. Background of the Invention

High quality video and audio signals and high bandwidth data signals (called “broadband” signals) are becoming increasingly desirable in today's digital world. A significant challenge is getting high bandwidth communications to end users, or reaching the so-called “last mile” market segment. Most U.S. metro centers are serviced by multiple providers over SONET fiber optic rings, with fiber to certain major buildings. Many, if not most, buildings, are not on fiber rings, however, and laying fiber can be time consuming and prohibitively expensive. In some instances, it may be practically impossible to obtain property rights-of-way to provide a high-bandwidth connection to the desired location.

While wireless radio frequency (RF) systems can provide data rates of 155 Mbps, there is limited spectral bandwidth available, communication licenses are generally required, the possibility for mutual interference exists, and the requisite equipment is expensive. Extending to higher data rates is difficult for RF frequencies with good atmospheric propagation characteristics.

Atmospheric laser communication provides a potential alternative for wireless point-to-point communications of high bandwidth signals. For instance, laser transceivers are capable of sending high bandwidth signals through the atmosphere. However, commercially available laser systems capable of transmitting high bandwidth signals across distances longer than a small city block are prohibitively large and extremely expensive. Moreover, several challenges must be overcome to facilitate high bandwidth laser communications over significant distances. One consideration is ensuring reliable communications despite varying atmospheric conditions. Since conditions such as fog in particular are difficult for low power laser beams to penetrate, ensuring uninterrupted atmospheric laser communications requires the use of high power lasers. A second design consideration is preventing high power laser beams used in an atmospheric laser system from causing eye or tissue damage if received by people. At short wavelengths, non-eyesafe power levels can permanently damage the eye before the victim becomes aware, because the retina has no pain sensors

Further complicating the use of atmospheric lasers is a phenomenon called scintillation that causes the random fading of signals transmitted through the atmosphere. It is understood that the atmosphere is not homogeneous, in that the index of refraction of air is not constant due to wind or turbulence. The transmission of a beam of light through the atmosphere is subject to these variations in the index of refraction such that the beam may be momentarily deflected from a straight path. With such deflection, an observer of the beam perceives the source to be flickering. Such flickering is highly disruptive to data transmission. A solution may be found in aperture averaging, by increasing the size of the apertures of the receiving unit. The intensity of the source can, to a certain extent, mitigate losses in transmission where the sensitivity of the receiver is not correspondingly decreased. Often, however, physical and practical limitations detract from such solutions.

To significantly overcome the effect of scintillation, spatial diversity transmitters have been constructed which employ multiple diode lasers arranged to produce displaced parallel beams. As these beams diverge, they overlap one another. A receiver displaced from the transmitter thus receives uncorrelated light at the receiver when aligned with the beams. As it is unlikely that all beams will be simultaneously diverted, the receiver is able to receive uninterrupted data from at least some of the plurality of transmitters. It has been found that the normalized standard deviation of the intensity at the receiver is reduced by the square root of the number of transmitting elements when properly separated. Reference is made to W. M. Bruno, R. Mangual, & R. F. Zampolin, Diode Laser Spacial Diversity Transmitter, pp.187-194, SPIE vol. 1044, Optomechanical Design of Laser Transmitters and Receivers (1989), the disclosure of which is incorporated herein by reference.

One structural application of the very principles presented in the foregoing publication is found in U.S. Pat. No. 5,777,768, the disclosure of which is also incorporated herein by reference. Transceivers using spaced multiple laser transmitters are used for two-way communication.

Another example of laser transceivers used for communications purposes may be found in application Ser. No. 09/434,913, filed Nov. 5, 1999, for a Portable Laser Transceiver, the disclosure of which is further incorporated herein by reference. The portable laser transceiver disclosed therein is capable of transmitting near-broadcast quality video, audio, and Ethernet signals.

For broadband fiber optic applications, a number of pre-fabricated integrated circuits are available for driving lasers at data rates of 1 gigabit per second (Gbps) or more. These laser drivers are used to drive the now-common fiber optic networks. These integrated circuits, however, are inadequate for high power lasers used in atmospheric laser communications, as they typically provide drive current capability of only 50 to 75 mA. Such low drive current is insufficient to overcome the effects of atmospheric scintillation at distances beyond of approximately the length of a laboratory.

When a high power laser is used, one method that has been used to achieve the high drive current needed to overcome atmospheric scintillation effects is the use of a RF Bias-Tee. This method typically uses a 50 ohm bias tee, thus coupling the broadband signal into a 50 ohm load—typically consisting of a 47 ohm matching resistor in series with a 3 ohm laser diode—to achieve a broadband match. The RF bias-tee approach, however, is not practical for high drive currents because the majority of the output power is wasted in the matching resistor. For example, a 700 mA drive current typically results in 5.8 watts of power dissipation in the 50 ohm bias tee.

A high current 4:1 broadband RF transformer may be used with a bias-tee approach to double the output drive current and transform the 50 ohm into a 12.5 ohm source, as seen by the load. However, this alternative approach still requires a 9 ohm resistor to match the source to a 3 ohm laser diode. Thus, the majority of the drive power is still wasted in the matching resistor. A transformer with a higher ratio could theoretically solve the lost power problem, but high ratio transformers capable of handling currents in excess of 200 mA and having a broadband response of up to 1 Ghz are not available.

U.S. Pat. No. 5,521,933 discloses a method of positioning the laser diode remotely from the driver circuit to reduce the effect on the laser diode of heat generated by the driver circuit. This method still uses a matching resistor, located remotely from the laser diode, which again causes power loss in the output drive current.

Regardless of the driving frequency, when driving a laser diode at high power, it is frequently desirable to use a thermoelectric cooler (TEC) to maintain the temperature stability of the laser diode. In many applications, the temperature stability of the laser diode may be important to maintain the output signal of the laser diode within a specified set of parameters. The cooling function of a TEC is controlled by a TEC controller circuit. Typical implementations of TEC controllers are either pulse-width-modulated (PWM) or proportional controllers. PWM controllers are undesirable for use in communication systems with sensitive receivers because PWM controllers tend to generate unwanted noise. Proportional controllers such as the proportional integral-differential (PID) type are therefore commonly used in such communication systems.

PID controllers, however, tend to dissipate the most heat when maximum cooling at the laser diode is required. The heat dissipation occurs because PID controllers function as a current source, having a compliance voltage that is significantly less than the supply voltage. For example, a PID controller operating off a 5V supply at its maximum rated current output typically has a useable compliance voltage of about 3V. The difference between the supply voltage and the useable compliance voltage tends to be dissipated in the controller as heat. Thus, in the most demanding cooling conditions such as hot weather, a PID controller tends to generate even more heat.

A need, therefore, exists for small and efficient, yet powerful laser transceivers that are capable of transmitting and receiving high power and high bandwidth signals across distances greater than a single city block. A need also exists for a means to efficiently cool high powered laser transmitters used in such transceivers.

SUMMARY OF THE INVENTION

The present invention is directed to transceivers using laser light as the carrier and methods for laser communication for transmitting broadband signals. Transmitter and receiver modules are contemplated. Use of a high power, high frequency laser driver facilitates free space communication across distances of at least eight kilometers in favorable weather conditions, and at least approximately two kilometers in foggy conditions according to a London, England fog environment with 99% availability.

In a first separate aspect of the invention, a high power, high frequency laser driver includes a power amplifier with a low output impedance suited to drive a laser diode. The power amplifier is operated as a voltage-controlled current driver for the laser diode. The laser driver is capable of providing very high current modulation, at least 100 mA, at high data rates, at least 10 Mbps, to a laser diode.

In a second separate aspect of the invention, a laser transceiver includes an input, a regenerator, a splitter receiving signals from the regenerator, a plurality of high power and high data rate laser drivers, and a plurality of lasers transmitting high bandwidth signals of the splitter. At least one digital signal may be transmitted.

In a third separate aspect of the invention, a transceiver having a regenerator includes a clock and data recovery circuit having multiple switchable digital data rates. This switching may be performed by software.

In a fourth separate aspect of the invention, a laser transceiver includes a fast reflector characterized by a low f-number, a long wave pass background rejection filter adjacent to the focal point of a the reflector, and a photodiode having a predictable responsivity roll-off at a wavelength above the long wave pass frequency. The resulting combination effectively operates like a bandpass filter.

In a fifth separate aspect of the invention, a high power laser diode is stabilized against temperature fluctuations with an efficient thermoelectric cooling system. Aided by a temperature sensor, a thermoelectric cooler in thermal communication with a laser diode is coupled with a power amplifier that is operated as a controlled current source to supply current to the thermoelectric cooler at near-perfect efficiency when maximum cooling is required.

In a sixth separate aspect of the invention, a stand-alone radio frequency transceiver is operated with at least one laser transceiver in overflow mode. A router is used to monitor and distribute incoming data signals between the laser and RF transceivers to promote enhanced total system bandwidth capability and low switching latency.

In a seventh separate aspect of the invention, a laser transceiver is enclosed within a protective enclosure and includes an environmental control system to maintain appropriate conditions for the transceiver to operate.

In a eighth separate aspect of the invention, a laser diode is thermally coupled with a thermoelectric cooler and then enclosed within a housing having integral heat sinks to draw heat away from the diode by way of the thermoelectric cooler.

In an ninth separate aspect of the invention, a transceiver has a plurality of laser diodes, each of which is coupled with a lens for receiving and collimating the laser output into a beam, with the lenses subject to beamwidth adjustment. Beamwidth adjustment between 0.3 and greater than 3.5 mrad is provided.

In a tenth separate aspect of the invention, a laser transceiver that is independent of particular digital protocol and is switchable between different data rates is provided. The transceiver may operate on different physical layers including STS-3, STS-12, OC-3, and OC-12, and support various digital signal protocols including TCP/IP, IPX, Fast Ethernet, SONET, and ATM.

In an eleventh aspect of the invention, any of the foregoing aspects are contemplated in combination for additional advantage.

Accordingly, it is an object of the present invention to provide an improved transceiver using laser communications, and an improved laser driver. Other and further objects and advantages will appear hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

In the figures, wherein like numbers reflect elements having similar function: [0032]
FIG. 1 is a schematic drawing of a laser communication system; [0033]
FIG. 2 is a front view of a transceiver according to a first embodiment; [0034]
FIG. 3 is a side view of the transceiver in FIG. 2; [0035]
FIG. 4 is a schematic diagram of a transceiver and associated devices according to a second embodiment; [0036]
FIG. 5 is a side sectional view of a transceiver and associated housing according to a third embodiment; [0037]
FIG. 6A is a front perspective view of a front portion of the housing depicted in FIG. 5; [0038]
FIG. 6B is a rear perspective view of a front portion of the housing depicted in FIG. 5; [0039]
FIG. 7A is a front perspective view of a rear portion of the housing depicted in FIG. 5; [0040]
FIG. 7B is a front perspective view of a rear portion of the housing depicted in FIG. 5; [0041]
FIG. 8 is a schematic diagram of a transceiver according to a fourth embodiment; [0042]
FIG. 9 is a schematic diagram of a laser driver that may be used with the transceivers of FIG. 5 or [0043] 8;
FIG. 9A is a first magnified portion of the schematic diagram depicted in FIG. 9; [0044]
FIG. 9B is a second magnified portion of the schematic diagram depicted in FIG. 9; [0045]
FIG. 9C is a chart showing the values of components in the schematic diagrams depicted in FIGS. 9A and 9B; [0046]
FIG. 10 is a schematic diagram of a complementary circuit for the laser driver of FIG. 9; [0047]
FIG. 10A is a first magnified portion of the schematic diagram depicted in FIG. 10; [0048]
FIG. 10B is a second magnified portion of the schematic diagram depicted in FIG. 10; [0049]
FIG. 10C is a third magnified portion of the schematic diagram depicted in FIG. 10; and [0050]
FIG. 10D a chart showing the values of components in the schematic diagrams depicted in FIGS. [0051] 10A-C.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Turning in detail to the drawings, FIG. 1 illustrates a [0052] laser communication system 10 comprising a first laser transceiver 12 and a second laser transceiver 14, each transceiver 12, 14 having a digital signal input 20 and digital signal output 22 that carry the communication signals being transmitted and received. The signal input 20 and the signal output 22 may carry either electrical or optical signals of various types. Compatible electrical signals may be carried on electrical cables such as Category 5 cable with RJ 45 connectors, for example, and the signals may conform to protocols such as TCP/IP, IPX, Fast Ethernet, or others known in the art, operating on physical layers such as STS-3, STS-12, or others known in the art. Compatible optical signals may be carried on fiber optic cables, and the signals may conform to protocols such as SONET, ATM, or others known in the art, operating on physical layers such as OC-3, OC-12, or others known in the art.
[0053] Electronics 16, 18 within each transceiver 12, 14 use the digital signal input 20 to drive the outgoing laser signals and convert the incoming laser signals into appropriate digital signal output 22. Preferably, the laser communication system 10 is capable of transmitting and receiving laser signals a bandwidth of at least 155 Megabits per second over distances of at least eight kilometers in favorable weather conditions, and at least approximately two kilometers in foggy conditions according to a London, England fog environment with 99% availability. More preferably, the system is capable of transmission across like distances and conditions at a bandwidth of at least 622 Megabits per second.
Preferably, each laser has a nominal output wavelength of 1.5 μm. One of the principal advantages of 1.5 μm wavelength is that are eyesafe intensity levels are approximately 50 times greater than at 0.8 μm. This is because for near-infrared wavelengths longer than 1.4 μm, the light is absorbed by the lens and cornea, and is not focused onto the retina. For 1.5 μm, the eyesafe power levels are the same as levels for heating of the skin, as it is the same effect. Also, at short wavelengths, non-eyesafe power levels can permanently damage the eye before the victim becomes aware, because the retina has no pain sensors. At 1.5 μm, if non-eyesafe power levels are encountered, the sensation of heat (or even pain) can be felt on the surface of the eyeball, and the natural blink reflex is induced. [0054]
The use of 1.5 μm wavelength has other benefits. Since the eyesafe intensity level at 1.5 μm is 50 times greater than at 0.8 μm, and since the intensity is inversely proportion to the square of the aperture diameter, this means that for a given power level, the diameter of the transmitting aperture can be seven times smaller at 1.5 μm than 0.8 μm. This facilitates the use of multiple transmitting apertures for scintillation reduction. Additionally, atmospheric attenuation is reduced at 1.5 μm relative to shorter wavelengths. The 1.5 μm wavelength region also corresponds to the low loss region for modern fiber optics. [0055]
FIGS. 2 and 3 illustrate one embodiment of a [0056] transceiver 50 directed to laser communication. FIG. 2 shows a front view of the transceiver 50 having a front plate 52 with a large centrally located receiving aperture 54 and four laser apertures 56 spaced about the receiving aperture 54. The diameter of the receiving aperture 54 is approximately twenty (20) centimeters. A narrow support beam 58 crosses the receiving aperture 54 and supports a photodiode 60, a background filter 61, and, if needed, one or more field correcting lenses 63, all of which are centrally located in relation to the receiving aperture 54.
High [0057] power laser transmitters 62 are disposed within each of the laser apertures 56 such that the laser transmitters 62 emit beams that are substantially parallel to each other. Each laser diode 62 responds to an amplified laser data signal to generate an intensity modulated light signal. Each laser 56 preferably produces an average power of at least eighty (80) milliwatts and has a nominal wavelength of 1,550 nanometers (1.5 μm), within the eyesafe region. As the laser diode 62 tends to emit a wide angle signal of about 300 cone angle, a lens 55 receives the laser output. The lens design is flexible in setting the beamwidth; that is, the beamwidth may be adjusted during production by adjusting the spacing between the lens 55 and the laser diode 62. This adjustment may be made by way of a threaded connection, or, more preferably, by using a vacuum chuck and micrometer positioner to position the lens. Once the desired lens position is reached, the lens 55 may be epoxied in place. After the epoxy is cured, the vacuum is released, and the micrometer positioner is removed. The range of beamwidth (i.e. beam divergence angle) adjustment provided by the lens 55 ranges from 0.3 mrad to greater than 3.5 mrad. If the laser diode 54 has a spatially elliptical output, a circularizing optic (not shown), which may be a cylindrical lens or prism pair, may be added. As noted before, the lasers 54 are all aligned such that the collimated beams are parallel.
A [0058] sighting scope 64 may be located along an outer portion of the front plate 52 for aiming the transceiver 50 at a second transceiver (such as the transceiver 14 shown in FIG. 1). As the sighting scope 64 is intended for initial alignment of a transceiver pair (e.g., the laser transceivers 12,14 shown in FIG. 1), the sighting scope 64 may be removed after this alignment is attained. Alternatively, a CCD (charge coupled device) sensor 65 may be added to a transceiver 50 and used to facilitate alignment of a transceiver pair. Connection of the CCD 65 (or CCD 256 in FIG. 8) with a controller 250 is illustrated schematically in FIG. 8. When the CCD 65, 256 is coupled with a controller 250, a frame grabber 257 extension to the controller 250 may be used to capture images of what is within the line of sight of the transceiver 12. Such images may be transmitted or downloaded from the controller 250 to a remote location, with an external interface operating a protocol such as SNMP, Ethernet, or another protocol known in the art.
Referring now to FIG. 3, the [0059] front plate 52 is connected to a rear plate 66 using support rods 68. The rear plate 66 supports a focusing reflector 70, which is centrally aligned with the receiving aperture 54 such that the photodiode 60 is positioned at the focal point of the focusing reflector 70. The focusing reflector 70 is approximately equal in diameter to the aperture 20 and facing in a parallel direction with the lasers 62.
The receiver portion of the [0060] transceiver 50 includes a receiving aperture 54, a focusing reflector 70, a photodiode 60, a background rejection filter 61, and electronics 72. The focusing reflector 70 focuses the incoming optical beam onto a photodiode receiver 60. The fast design enables the large aperture 54 for collection efficiency, yet provides a very short focal length—both for compactness, and to achieve the largest field-of-view for a given detector diameter. The preferred f-number of the reflector 70 is approximately 0.67. As the f-number of the focusing reflector 70 decreases, off axis optical aberrations increase.
Mangin mirror or parabolic reflector approaches may be used for the focusing [0061] reflector 70 according to separate embodiments. A catadioptric design, the Mangin mirror is a negative meniscus lens with a mirrored rear surface which combines a compact overall design with a short focal length. The presence of both reflective and refractive elements in a Mangin mirror provides sufficient degrees of freedom to keep the amount of optical aberration within acceptable limits over the entire optical field of view, such that no additional optical corrector lens is necessary.
A parabolic reflector may be used for the focusing [0062] reflector 70 according to an alternative embodiment. A parabolic reflector has a single reflective surface, and requires one or more field corrective lenses to sufficiently correct aberrations. The parabolic reflector may therefore comprise one or more optical elements 63 to control the amount of aberration near the edges of the field of view. In placing the corrector lenses 63 near the focal plane, the corrector lenses 63 may be mounted in the same mechanical assembly that holds the detector 60. Multiple corrector lenses may be placed thusly to provide a higher degree of aberration control.
In a third reflector embodiment, the focusing [0063] reflector 70 comprises a mirror having a more general conic or aspheric optical surface and one or more corrector lenses (not shown). A conic or aspheric mirror provides a limited amount of aberration control, thus reducing the number of corrector lenses needed to properly focus the incoming signals.
To reduce interference and background noise from ambient light and other sources, the optical path of the receiver advantageously includes a flat or hemispherical [0064] background rejection filter 61. The filter 61 may be comprised of alternating layers of dielectric material deposited on a glass or crystalline substrate. This construction results in a peak transmission at band center of over 65%. The filter 61 may be located at the receiving aperture 54. However, such a configuration requires a large and costly filter, adding weight and size to the assembly 50. Preferably the filter 61 is located between the focusing reflector 70 and the photodiode 60. A bandpass filter nominally centered at 1500 nanometers may be used. However, if the bandpass filter is a flat multilayer dielectric filter, when receiving light rays from both small and large angles of incidence with respect to normal characterized by a low f-number optical system, then the passband is shifted for the different angles of incidence. To correct this, then, a much larger passband for a flat filter is to be used (about a 400 nanometer filter), or a hemispherical filter may be used since all of the incident rays are normal to the filter surface. A hemispherical filter centered at the nominal laser wavelength of 1,550 nanometers and having a passband width of 100 nanometers or less may be used.
A bandpass filter inherently requires the use of multilayer dielectric technology. A long wave pass approach may be used in conjunction with a [0065] detector 60 having predictable responsivity roll-off to create an effective bandpass filter. In one embodiment, the detector responsivity rolls off significantly between 1500 and 1700 nm, and is effectively zero beyond 1700 nm. Coupling this detector 60 with a long wave pass filter transmitting 1500 nm and above wavelength, the resulting combination provides an effective bandpass filter. A long wave pass filter, as used in conjunction with a detector as described above, may be dielectric, and flat or hemispherical in shape. As an alternative to a long wavepass multi-layer dielectric filter, the filter 61 may be an absorptive filter.
If a [0066] hemispherical filter 61 is used, its center of curvature is located near the focal point of the reflector 70. Using a standard TO-8 size detector package results in a hemispheric filter dome having an outer diameter of approximately twenty-two (22) millimeters and a thickness of 2.5 millimeters. In an embodiment utilizing one or more corrector lenses 63, the corrector lenses 63 may be used to create an afocal region in front of the photodiode 60 in which a filter 61 having a flat shape would be placed.
The transceiver may also include a sealed [0067] protective enclosure 74 as shown in FIG. 3. The protective enclosure 74 protects the transceiver from weather conditions and provides an enclosed environment in which the transceiver may operate. At the front cover of the protective enclosure 74 is an acrylic filter 76 covering the large aperture 54. The acrylic filter 76 is transparent to the operational wavelength of the laser transmitters 62, but limits transmission of visible light to prevent introduction of noise and heat from this light. Further, a stray light baffle 75 is preferably placed between the transceiver 12 and the acrylic filter 76 to reduce interference from stray light, and electromagnetic and RF sources. The baffle 75 is preferably a honeycomb of thin aluminum, approximately three inches in thickness, with a face-to-face hex cell size of approximately {fraction (11/32)} inch.
FIG. 4 is a schematic representation of a [0068] laser transceiver 100 according to another embodiment. The transceiver 100 includes a combined laser transmitter/laser driver module 110, a receiver module 120, and associated electronics 130. Starting with the receiver module 120, an incident laser beam is reflected by a reflector 122 and focused through a background rejection filter 123 onto a photodiode 124 located at the focal point of the focusing reflector 122. From the photodiode 124, the signal is carried to a preamplifier 125 preferably contained within the laser receiver module 120, and then sent to signal conditioning electronics 131. After conditioning, the signal is provided to an output signal interface 132, which may include a fiber transmitter for transmitting an optical signal to a fiber optic cable. Electrical signals may alternatively be output, such as via a Category 5 cable. A switching device 140, which may include a switch or router portion to enable transmission of various electrical or optical signals (including TCP/IP, IPX, Fast Ethernet, SONET, ATM, or other signal types, on various physical layers such as STS-3, STS-12, OC-3, or OC-12) receives the output signal.
In the illustrated embodiment, the [0069] switching device 140 is coupled to a computer 142 having a network interface card 143. The personal computer 142 may further have an audio/video interface card 144 for receiving audio and video signals. The switching device may be connected with various electrical or optical input types, such as Category 5 cable using RJ-45 connectors, or fiber optic cable. An optional stand-alone RF (radio frequency) backup transceiver 146 may further connect to the switching device 140.
On the input/transmitter side, high bandwidth digital input signals are provided to the [0070] transceiver 100 via a switching device 140. A high bandwidth signal is conventionally considered to be a signal of 10 Mbps or greater. One skilled in the art will recognize that any high bandwidth signal may be used as input to the transceiver 100, so long as appropriate electronics are provided, when necessary, to convert the high bandwidth input signal into a high bandwidth digital signal. Input signals may be provided through the switching device 140 to the transceiver 100 by way of an input signal interface 134, which in one embodiment may include a fiber optic receiver for receiving digital signals from a fiber optic cable. The signal is then provided to signal conditioning electronics 135, and thereafter provided to a splitter 136. The splitter 136 splits the signal into four identical signals at one-quarter of the power. Each signal emerging from the splitter 136 is provided to a laser driver circuit 111 and ultimately provided to a laser diode 115. The laser driver circuit 111 includes a DC bias circuit 112 and a high power, high bandwidth power amplifier 114 for driving the laser diode 115. A high power laser driver is conventionally considered to be a laser driver operating at a nominal level of 100 mA or greater. The high power, high bandwidth laser driver circuit is discussed in detail hereinafter, in connection with FIGS. 9-10C. The output of the laser diode 115 is provided to a lens 116, and may be monitored with a fiber optic segment 117 and fed to a photodiode 118 for monitoring the output of the laser diode 115. A thermoelectric cooler 119 and its associated controller 113 are provided to control the temperature of the laser diode 115. The controller 113 is coupled with the thermoelectric cooler 119, which is in thermal communication with the laser diode 115. The controller 113 and the thermoelectric cooler 119 act in conjunction with a temperature sensor (not shown) to stabilize the temperature, and thus the output power, of the laser diode 115. The optimum operational temperature of each laser diode 115 depends on the specifications for the particular laser diode used, as provided by the laser diode manufacturer.
Preferably, output of the [0071] laser diode 115 is monitored. One method of monitoring the laser diode 115 is by monitoring its input current, but this method is indirect. A better method is to monitor the transmitted light signal from the laser diode 115. One method of monitoring the light signal is by way of a fiber optic element 117 that may extend into the transmitted light signal from the laser diode 115. This fiber optic element 117 is coupled with a photodiode 118. More preferably, the laser diode 115 is provided with an integral monitor photodiode (not shown), which eliminates the need for a separate fiber optic element 117. The output of the photodiode may be coupled with the modulation signal amplifier 114 to use the sampled laser diode output for controlling the amplifier 114 and in turn the signal strength, thus permitting operation in constant optical power mode. Thus, the modulation signal amplifier 114 may be made responsive to the output of the photodiode 118.
FIGS. 5, 6A, [0072] 6B, 7A, and 7B illustrate an alternative compact and high power laser transceiver 150 and its associated housing 151. The housing 151 is designed to both mount the operative components and serve as a protective enclosure suitable for outdoor use. Only three parts, namely, a front portion 152, a rear portion 153, and a snout 182, are designed to interconnect to form the housing 151 to fully enclose the transceiver 150. Of these three parts, the optical payload mounts to only one: the front portion 152. This construction promotes precise positioning of the optical components, since in comparison to the embodiment of FIGS. 3-4, this approach limits the adverse effects of additive dimensional tolerances for multiple structural parts. The front portion 152 includes prominent annular heat sinks 184 to dissipate heat from laser diodes (such as the laser diodes 115 shown in FIG. 4) and from laser drive circuits and associated electronics (such as shown in FIG. 4) contained within the housing. More specifically, an inner surface of each heat sink 184 is in thermal communication with at least one thermoelectric cooler (such the pair of thermoelectric coolers shown in FIG. 8), which in transmit heat from the laser diodes (such as shown in FIGS. 4, 8) to the heat sinks 184. Preferably, an annular thermoelectric cooler disposed around the laser diode 115 is used.
The [0073] front portion 152 is preferably cast from a lightweight aluminum alloy, but may alternatively be manufactured by various techniques from a variety of suitably durable, strong, and thermally conductive materials, including steel. The housing 151 is designed to mate with the optical payload at four flat interior payload mating surfaces 179 adjacent to the laser apertures 156, preferably by way of screws and tapped holes. The payload mating surfaces 179 further serve as a primary contact surface for transferring heat from laser diodes to the heat sinks 184 by way of thermoelectric coolers. The cast housing 151 is preferably machined along the payload mating surfaces 179 to ensure that all four payload mating surfaces 179 are commonly flat. The front portion 152 is preferably painted to reduce effects of corrosion when subjected to outdoor use. The rear portion 153 does not contain any dedicated heat sinks 184, and therefore does not necessarily need to be fabricated from a thermally conductive material. The rear portion 153 may be manufactured from a plastic suitable for outdoor use, but could also be manufactured using other techniques and other durable materials including metals.
The [0074] front portion 152 and rear portion 153 mate along a common surface 155 to form the housing 151 that encloses a reflector 170, four laser transceivers (not shown), a photodiode 160, a background rejection filter 161, one or more field corrector lenses 163, and various electronics 172. The photodiode 160, background rejection filter 161, and one or more field corrector lenses 163 are disposed at the focal point of the reflector 170, and supported by way of a narrow support rod 158 placed across a primary aperture 154. Adjacent and connected to the front portion 152 of the housing 151 is a snout 182 across the primary aperture 154. The snout 182 preferably includes a honeycomb baffle 175 and acrylic filter 176 for the same reasons discussed above in another transceiver embodiment. The snout further includes a protruding hood 183 that further reduces interference from incident light and provides a measure of weather protection for the front cover 177.
Wired (electrical or optical) data and power signals to and from the [0075] transceiver 150 are carried to the transceiver 150 by a conduit 186. The transceiver 150 may be supported from below by way of a mounting element 187. The mounting element 187 preferably the angular position of the transceiver 150 to be adjusted to facilitate aiming the transceiver 150 at a similar transceiver located remotely.
FIG. 8 provides a schematic representation of a [0076] wideband laser transceiver 200 according to a fourth embodiment. On the input side, the transceiver 200 includes various input signal electronics 202, a laser driver circuit 220, and a laser transmitter module 225 with associated thermoelectric coolers 226, 227. On the output side, the transceiver 200 includes a laser receiver module 229 and various output signal electronics 230. In the illustrated embodiment, the transceiver 200 further includes an associated controller 250 in communication with an environmental control system 252, at least one temperature sensor 254, a CCD sensor 256, and an interface for diagnostics, monitoring, network management, and/or control 258. The controller 250 may further include a frame grabber 257, may receive signal level information from the receiver module 229, and may receive monitoring information from the laser diode.
Turning to the input/transmitter side, a first input signal is provided to an [0077] input signal interface 204. The input signal is a wideband digital signal, either electrical or optical, according to a variety of signal types (including TCP/IP, Fast Ethernet, SONET, ATM, or other signal types known in the art, on various physical layers such as STS-3, STS-12, OC-3, or OC-12). Various electrical or fiber optic cable connectors may be received by the input signal interface 204 depending on design requirements. Upon receipt of the digital input signals, these signals are provided to a regenerator 206. The regenerator 206 preferably includes an input signal amplifier 207, either a limiting amplifier or automatic gain control, to provide gain, as necessary, and smooth out variations in input signal amplitude. The regenerator 206 further includes a first clock/data recovery circuit 210 to provide protocol independence. The first clock and data recovery circuit 210 includes at least one oscillator 212, such as a crystal, to regulate the clock frequencies. When more than one oscillator is provided, the integrated circuit utilizes two phase locked loops to permit modulation as different frequencies, so as to accommodate more than one data transmission protocol, such as TCP/IP, Fast Ethernet, SONET, and ATM. Thus, a single transceiver 200 is enabled to transmit and receive more than one of the aforementioned protocols. Switching between clock frequencies may be performed by manually substituting an existing oscillator 212 with an oscillator of a different frequency. More preferably, as shown in FIG. 8, multiple oscillators 212, 213 may be built into the transceiver 200, and a switch 214 may accomplish switching between the oscillators 212, 213. This switching may be controlled manually, or, more preferably, by a controller 250, such as by using transistor-transistor logic. Either oscillator 212, 213 provides a clock signal to the data recovery electronics 215.
Upon regeneration, the digital signal may be provided to an [0078] optional multiplexer 216 to be combined with at least one additional signal from a second input signal source 203. The additional signal may be of various types, such as T1, Ethernet, telemetry information, tracking information, or other signals known to those skilled in the art. Thereafter, the combined signal is provided to a splitter 218 that divides the digital signal input into four substantially equal components comprising the same signal input at one-quarter of the power. The four laser data signals are transported to a plurality of high power, high frequency laser driver circuits 220, each of which modulates a laser diode contained within the laser transmitter module 225. Only one of the four laser drivers 220 is illustrated. The remaining three laser drivers 220 and laser diodes (within the laser transmitter module 225) are preferably identical to those depicted. The laser diodes within the transmitter modules 225 are displaced from one another, aligned, and facing in parallel directions. As previously described, each diode preferably has a collimating lens (not shown).
In addition to modulating the laser diode within the [0079] laser transmitter module 225, the laser driver circuit 220 controls thermoelectric coolers 226, 227 associated with the laser diode to stabilize the temperature, and thus the output power, of the laser diode. Further details regarding control of thermoelectric cooler associated with the transceiver 200 will be discussed hereinafter.
Turning to the output/receiver side, an incident laser beam is received by the [0080] laser receiving module 229 and converted to a preamplified electrical signal. The signal is provided to output signal electronics 230, which includes several elements. First the signal is provided to a second regenerator 232. The regenerator 232 preferably includes a signal amplifier 234, either a limiting amplifier or an automatic gain control, to provide gain, as necessary, and smooth out variations in signal amplitude. The second regenerator 232 preferably further includes a second clock/data recovery unit 236. The second clock and data recovery unit 236 preferably also comprises a switchable dual oscillator such as the dual oscillator 212, 213 shown in connection with the first clock and date recovery unit 210, and operates in a similar manner. Upon regeneration, the resulting digital electronic signal may be provided to an optional de-multiplexer 238 to segregate at least one additional output signal 205. Following de-multiplexing, the digital signal remaining in the output signal electronics 230 is passed to an output signal interface 240. An output signal interface 240 converts the electronic signal into an appropriate output signal, such as an electronic or optical signal. Either electrical or optical interfaces may be provided, subject to the inclusion of appropriate hardware as would be apparent to one skilled in the art. In one embodiment, the output signal interface 240 includes a fiber transmitter that converts the electronic signal to an optical signal, and further includes a fiber optic connector for connecting a fiber optic cable. The primary output signal is a wideband digital signal, and may be in accordance with various protocols known in the art, including TCP/IP, IPX, Fast Ethernet, SONET, or ATM, and may operate on various physical layers known in the art, including STS-3, STS-12, OC-3, or OC-12. Although depicted separately, the output signal interface 240 and input signal interface 204 may be combined, and if the interfaces 204, 240 include a fiber optic transmitter and a fiber optic receiver, then an integrated fiber optic transceiver may be used.
A [0081] controller 250, preferably a microprocessor-based digital controller or computer, is advantageously provided, primarily to detect and monitor various aspects of the transceiver 200. This capability may provide both real-time and historical data logging for status monitoring, performance monitoring, network management, and/or troubleshooting. When the transceiver 200 is first powered, the computer 250 may sample the amount of current being supplied to the lasers through the laser drivers 220 to ensure that the lasers sufficient power to transmit signals. During operation, the computer 250 monitors the temperature levels of the laser diodes within the laser transmitter modules 225. If the temperature of any of the diodes exceeds the optimum operational temperature as specified by the laser diode manufacturer, then the computer 250 may take one or more steps to alleviate the overheating, such as alerting appropriate technical personnel, shutting down one or more of the laser transmitters 225, or any other appropriate actions. The computer 250 preferably also monitors the voltages supplied to the photodiodes (not shown), the modulation signal to the laser driver amplifier within the laser driver circuit 220, and the DC bias circuit (also part of the laser driver circuit 220). The measured voltages are preferably converted to a current value that is compared to pre-set values in a look-up table, customized for the individual laser diode, to further ensure the proper functioning of the transceiver 200. If the transmitted laser beam signal is monitored with a photodiode, the output of the photodiode may be coupled with the controller 250, to provide laser performance information, or permit the lasers to be operated at constant signal strength. The controller 250 may also monitor signal level from the laser receiver module 229. Furthermore, the controller 250 and may receive signals from a CCD sensor 256, and, utilizing a frame grabber extension 257, the controller 250 may capture images of what is within the line of sight of the transceiver 200.
One interface that may be used by the [0082] controller 250 to perform its functions is a RS-232 interface format utilizing SNMP (Simple Network Monitoring Protocol), although other interface formats, including establishment of an Ethernet connection with the controller 250, may alternatively be used. In a preferred embodiment, the controller 250 is a computer which is used primarily for diagnostic purposes and may be polled remotely using a modem, over the Internet using an (Ethernet) HTML browser, or other such communication means as are known in the art, thus permitting remote information monitoring and/or control. While the controller 250 is preferably a microprocessor-based digital computer, a dedicated digital signal processor may alternatively be used.
Additionally, the [0083] controller 250 interfaces with environmental controls 252 including additional temperature sensors 254, as may be provided within an enclosure surrounding the transceiver 200, to regulate the temperature and humidity experienced by the transceiver 200 and provide optimal environmental conditions for the transceiver 200 to operate. Heat sinks, such as the heat sinks 184 provided in FIGS. 5-6B may also be added to the outside of a transmitter enclosure or housing 151 to aid with environmental control.
Referring again to FIG. 4, a stand-alone radio frequency (RF) [0084] transceiver 146 is provided as a backup to the laser transceiver 50 during inclement weather conditions, particularly fog. In one embodiment directed to Fast Ethernet/OC-3 signals, the RF transceiver 146 operates at a frequency of 2.4 GHz and is capable of up to 11 Megabits per second (Mbps) bandwidth. One of several different methods may be utilized to switch between the laser transceiver 100 and the RF transceiver 146 when necessary. First, a router 140 may be utilized to monitor the laser transceiver 100 for repeated requests for retransmissions or packet errors. When the requests for retransmissions or packet errors reach a predefined level, then the router 140 switches over to the RF transceiver 146 for a predetermined amount of time. After such predetermined time, the router 140 switches back to the laser transceiver 100 and again monitors the laser transceiver 100 for requests for retransmissions or packet errors.
A second method that may be utilized to determine when to switch from the [0085] laser transceiver 100 to the backup RF transceiver 146 is by coupling the controller 250 (as shown in FIG. 8) to the preamplifier of the laser receiver module 229 (as shown in FIGS. 4, 8) to monitor the strength of the incoming signal. Using this method, once the incoming signal drops below a predefined level, the controller 250 divides the signal between the RF transceiver 146 and the laser transceiver 100. The RF transceiver 146 is used to send the data signals while the controller 250 continues to monitor the strength of the incoming signal from the laser transceiver 100. Once the strength of the incoming signal from the laser transceiver 100 returns to above the predefined level, the computer 250 switches back to using the laser transceiver 100.
A third method, called overflow mode, has the least latency of the methods. This method may be utilized to determine when to switch from the [0086] laser transceiver 100 to the backup RF transceiver 146 through the use of a router 140 to monitor and distribute the incoming data signals between the two transceivers 100, 146. All signals are initially routed through the laser transceiver 100 until the bandwidth of the laser transceiver 100 is entirely in use. Excess data signals are then routed through the RF transceiver 146. As the bandwidth of the laser transceiver 100 drops due to inclement weather, more data signals will be routed to the RF transceiver 146. Conversely, as the weather begins to clear and the laser transceiver 100 becomes more capable of carrying data signals, less data signals will be routed to the RF transceiver 146. This configuration has the further benefit of providing a higher total system bandwidth capability with less switching latency.
A [0087] laser driver 300, such as for use as the laser driver 220 depicted in FIG. 8, will now be described. Reference will be made generally hereinafter to FIGS. 9 IOC, which provide a laser driver schematic. The laser driver 300 essentially comprises a modulation signal amplifier to amplify the laser data signals, and a DC bias circuit to ensure that a laser diode 301 operates in a relatively linear range. The laser driver 300 is capable of providing very high current modulation, in the range of 100 mA to 1500 mA, at high data rates, in the range of 10 Mbps to 622 Mbps, to the laser diode 301. The ability to drive the laser diode 301 at such high rates derives from a unique configuration involving a power amplifier. The power amplifier, which is preferably a RF power FET, directly drives the low impedance laser diode using a low voltage power supply. A typical laser diode useful in this application has a characteristic dynamic impedance of between approximately 2 and 5 ohms. Preferably, the power supply voltage is less than 12 volts; more preferably, the power supply voltage is approximately 5 volts. Higher supply voltages may also be used, such as 12V, 15V, or 28V, but in using the higher supply voltages results in greater power consumption and wasted thermal load. In applications where the power consumption and thermal load is less of a concern, the higher supply voltages may be used to attain improved gain and bandwidth. Preferably the RF power FET is capable of operating at a minimum frequency of 1 MHz or less, and further preferably capable of operating at a frequency of at least 100 kHz.
FIGS. [0088] 9-10C illustrate an embodiment of the laser driver 300 in which the output stage of the RF power amplifier Q3 is coupled with a 5V supply. The circuitry illustrated in FIGS. 9-9C comprises the primary laser driver circuitry and is connected to the circuitry in FIGS. 10-10C through connectors J1, J2, J3. The circuitry illustrated in FIGS. 9-9C primarily comprises the laser bias current circuitry and the TEC controller circuitry. This particular embodiment of the laser driver 300 is designed to accept a digital input signal having an amplitude of 175 mV on a 50 ohm coaxial transmission line, with all the amplifiers operating at least 2 dB below the −1 dB power output compression point. In addition, this embodiment comprises three stages of amplification. In an alternative embodiment, two stages of amplification may be used.
As illustrated in FIGS. [0089] 9-9C, the input signal from the coaxial transmission line is AC-coupled into the first amplifier stage Q1, which may comprise an ERA-2SM or similar op-amp. The signal then passes to a digital attenuator U2, which may comprise an RF2420 or similar attenuator. The digital attenuator U2 reduces the signal amplitude by a minimum of the 2 dB insertion loss and up to a maximum of 30 dB or more. The signal passes from the attenuator to the second stage amplifier Q2, which may comprise an ERA-6SM or similar op-amp. The digital attenuator U2 may also be located after the second stage amplifier Q2. Following the second stage amplification, the signal is AC-coupled into the third stage power amplifier Q3, which may comprise an F2248 or D2202UK or device. In the embodiment shown, the power amplifier Q3 comprises a broadband RF power MOSFET. The power amplifier used should be one which provides the gain required as described herein and has at least a 1 GHz bandwidth. A silicon device may be preferred in certain instances over a GaAs device because the silicon device meets at least the minimum requirements and typically provides a cost savings over GaAs devices. The laser diode 301, the sense resistors R11, R19, and the power amplifier Q3 may alternatively be connected in series across the 5V supply voltage.
The first stage amplifier Q[0090] 1 and the second stage amplifier Q2 are broadband 50 ohm amplifier gain blocks. Alternatively, discrete RF transistors may be used in the first and second amplifier stages. In applications where the input signal has a higher voltage level, or in applications where less amplification is required to drive the laser diode, the first and second amplifier stages may be replaced by a single amplifier which provides the required gain for the input to the power amplifier Q3. In an alternative embodiment, the first stage amplifier Q1 may be a limiting amplifier that hard-limits a digital input signal to a fixed output lever, regardless of the input signal amplitude. Typically, this limit would be a PECL (positive emitter control logic) output level of 700 mV.
In the embodiment depicted in FIGS. [0091] 9-9C, the signal input to the second stage amplifier Q2 is at a higher voltage level than the signal input to the first stage amplifier Q1. Therefore, in order to achieve the desired overall amplification, the second stage amplifier requires a higher supply voltage, preferably greater than 7V. Alternatively, if the overall power consumption needs to be reduced and if the reduced overall amplification is sufficient for a particular application, the second stage amplifier Q2 may be operated from the same 5V power supply as the first stage amplifier Q1 and the power amplifier Q3. Supply voltages greater than 5V may also be utilized, however, using higher voltages results in proportionally greater power consumption and wasted thermal load. In the embodiment depicted, the 5V supply voltage has been chosen to decrease power consumption and the thermal load.
Each amplifier stage is thermally stabilized using accepted design techniques to compensate for current and gain changes as a function of temperature. Resistors R[0092] 2, R8, and R20 are therefore provided to the first, second, and third stage amplifiers respectively. A DC bias voltage is provided to each amplifier stage through one or more RF chokes in the form of inductors L4, L9, L7, L10, L2, L3, and L8. The RF chokes present a high impedance to any power supply noise that may range from 100 kHz to 1 GHz that could otherwise contaminate the amplified signal. Additionally, an AC-coupling capacitor C11 is provided to prevent the laser bias current from interfering with the DC operating supply voltage at the output of the power amplifier Q3.
The amplitude of the input signal to the power amplifier Q[0093] 3 is adjustable, thus enabling the laser driver 300 to accommodate laser diodes with differing drive current requirements. Adjustable feedback is therefore provided at the second stage amplifier Q2 by linking the output of the second amplifier Q2 to its input through and adjustable resistor R21. Such adjustable feedback could also be provided across the first stage amplifier Q1 or the power amplifier Q3. Alternatively, adjustable feedback could be achieved through the use of a voltage controlled variable gain amplifier at either the first or second stage of amplification, wherein a potentiometer would be used to adjust the gain of the amplifier.
The output drive current of the power amplifier Q[0094] 3 to the laser diode is adjusted to the nominal operating point of the laser diode by adjusting the gate voltage at the input of the power amplifier Q3. The gate voltage is controlled by a first integrated circuit U3 and a potentiometer R6. The first integrated circuit U3 is preferably a CD4051 BCM or similar device. The gate voltage is derived from a supply voltage regulated by a zener diode D1 to achieve a highly stable bias voltage regardless of power supply voltage fluctuations. The power amplifier stage Q3 is AC-coupled with the gate voltage such that the voltage waveform at the input results in a linear modulation of the laser drive current at the output. Therefore, the low impedance laser diode 301, being essentially a current-controlled device that linearly converts input current to output optical power, is driven by the voltage controlled power amplifier Q3 which resides in the low impedance power amplifier stage of the laser driver 300. The input and the output of the power amplifier Q3 are AC-coupled, and the output to the laser diode 301 is provided with an appropriate dc bias current such that the output modulation of the power amplifier Q3 causes the laser drive current to swing from nearly off to the desired output power with an optical output power extinction ratio of at least 10:1. In designing the bias circuit, consideration may be given to selecting minimum, maximum, and average power levels for the laser diode 301, as bias current causes the laser to operate at a selected average power level, and the wideband signal modulation will cause the laser output to vary between the power level extremes.
The [0095] laser driver 300 illustrated in FIGS. 9-9C also comprises circuitry for adaptive digital control of the output power of the laser driver 300. Such control over the output power may be desirable so that the output power can be reduced when high output power is not needed. Reducing the output power may enhance the overall life span of the laser diode by reducing operating stress levels during periods of operation. Control over the output power also enables the laser driver 300 to be used under a wider variety of circumstances. For example, the output power can be greatly reduced for communication links over short distances, thus avoiding saturating the receivers, and can be increased to maximum or near maximum levels in order to overcome inclement weather conditions.
Digital control over the output power is implemented by simultaneous control over three laser driver functions. First, the digital attenuator comprises a digitally controllable RF attenuator such as RF Micro Devices RF2420. A 3-bit control signal data[0096] 0, data1, data2 is used to select the attenuation of the modulation signal. Typically, a 1 to 3 dB insertion loss is selected, however, a 30 dB or more insertion loss may be selected as desired by the user.
Second, the laser bias current is also to be appropriately reduced to maintain the desired extinction ration of at least 10:1. The laser bias current is adjusted using multiplexer U[0097] 7, which is configured so that the same 3-bit control signal data0, data1, data2, selects a required discrete resistor value using resistors R33, R22, R29, R30, R31, and R32. The discrete resistor value is used to realize an appropriate laser bias current of up to 500 mA from the output of the laser bias current FET U4. This FET U4 preferably comprises an NDT 456 P or similar device. Potentiometer R18 is provided as a vernier control to set the nominal bias current required by the particular laser diode being used. The bias current output from FET U4 is applied to the laser diode through a broadband choke network comprising inductors L5, L6 to ensure any RF noise that might get picked up by the bias current circuitry is blocked and does not contaminate the laser modulation current.
The third function controlled by the 3-bit control signal is the gate bias voltage for the power amplifier Q[0098] 3. This adjustable gate bias voltage is accomplished using multiplexor U3 configured so that the 3-bit signal data0, data1, data2 selects a required discrete resistor value using resistors R5, R7, R25, R9, R22, or R26. The discrete resistor value is used to realize an appropriate FET gate bias voltage for linear operation and minimum power consumption in the power amplifier Q3. Potentiometer R6 is provided as a vernier control to set the nominal bias current required by the particular laser diode being used. Ferrite core inductor L2 is provided as an inductive choke to prevent RF noise that may be present on the gate bias voltage from contaminating the modulation signal at the input to the power amplifier Q3.
The [0099] laser driver 300 may also incorporate, as an optional feature, a low bandwidth signal into the broadband communications signal. This narrowband signal may be used, for instance, for telemetry or tracking. The narrowband signal is to be of a lower bandwidth so that it does not interfere with the communications signal. In the embodiment of the transceiver described herein, the communications signal operates on a frequency of greater than 100 kHz, therefore, in order to avoid contaminating the communications signal with the narrowband signal and to permit convenient filtering of the narrowband signal from the communications signal, the narrowband signal preferably occupies a frequency range less than 100 kHz, and more preferably less than 50 kHz. Additionally, because atmospheric scintillation primarily occupies the frequency range below 200 Hz, the narrowband signal preferably occupies a frequency range greater then 200 Hz to avoid corruption through the AC-coupling. Such a narrowband signal may be used by the first transceiver to communicate with the second transceiver the signal strength being received. Thus, when the output power of the laser diodes requires an increase or decrease, the transceivers may communicate such a need and automatically compensate their respective output powers using the aforementioned optional digitally controlled power feature.
In FIGS. [0100] 9-10C, such a narrowband telemetry signal is incorporated through the laser bias circuitry. The narrowband modulation signal is imposed upon the DC laser bias current, and therefore imposed upon the output of the laser driver to the laser diode. The narrowband modulation input to the DC bias current is a standard TTL interface into an analog switch U5. A potentiometer R17 is used to set the desired ratio of the narrowband current to the DC bias current. Preferably, the narrowband current is less than 20% of the DC bias current. More preferably, the modulation amplitude of the narrowband signal is less than 10% but more than 5% of the DC bias current. For example, a nominal 350 mA DC bias current is preferably modulated by a narrowband signal having a 20 to 35 mA range. Amplifiers U3B and U3C superimpose the narrowband modulation on the DC bias current originating at resistor R18. If no narrowband input is provided into the analog switch U5, the DC bias circuit provides only a steady DC bias current.
Baud rates ranging from 100 bps to 100 kbps may be accommodated by the narrowband signal with the circuitry herein described. For example, in one implementation the narrowband signal may comprise a 9600 bps Manchester-coded bit stream at 19.2 kBd, a signal which occupies a spectrum ranging from approximately 500 Hz to 20 kHz. [0101]
A second optional feature included in the laser driver illustrated in FIGS. [0102] 9-10C is monitoring circuitry that senses the DC bias current (“bias-test”) and the peak-to-peak amplitude of the laser modulation current (“RF-test”). This monitoring circuitry, when included, is preferably coupled to the aforementioned controller 250. The DC bias current is monitored through an op-amp U3D which senses the voltage drop across two in parallel resistors R11, R19, providing a 0.5 ohm impedance, in series with the laser diode drive current. The laser modulation current amplitude is monitored by sensing the modulated voltage across the same two in parallel resistors R11, R19, wherein the modulated voltage is amplified by an op-amp Q4, rectified by a diode pair D7 and integrated by a capacitor C29 and a resistor R38 at the input to op-amp U3A. The op-amp U3A generates the monitor voltage “RF-test out” that is linearly related to the laser modulation current amplitude.
Yet another optional, but preferred, feature included in the laser driver is a thermoelectric cooler (TEC) controller. A TEC is used to stabilize the temperature of the laser diodes against temperature fluctuations, thus reducing thermal stress. Reducing thermal stress to the laser diode typically stabilizes laser wavelength over time and enables the laser diode to have a longer life. The TEC controller as described herein permits highly efficient control over the TEC under circumstances where the laser drivers are operating at maximum load, even in conditions of hot weather. In fact, operating of the thermoelectric cooler power amplifier as a controlled current source to supply the thermoelectric cooler results in near-perfect efficiency when maximum cooling is required. [0103]
The TEC controller illustrated in FIGS. [0104] 9-10C operates off a 5V supply. A power FET U8, preferably an NDT 456P or similar device, is used as a voltage-controlled current source to supply current to the TEC. The power FET U8 and the TEC TM2 are connected across the 5V supply. The TEC TM2 used preferably (1) provides the required maximum cooling capacity when operated at a near-optimum current, and (2) has an impedance at this optimum operating current that results in a 5V drop across the TEC TM2. Thus, when maximum cooling capability is required of the TEC TM2, the 5V supply voltage is dropped entirely across the TEC TM2 and only about 0.1V is dropped across the power FET U8, resulting in greatly enhanced efficiency under the most thermally stressing conditions. The power FET U8 is controlled through four op-amps U1A, U1B, U1C, U1D, which preferably comprise an LM2902M or similar device.
A thermistor TM[0105] 1 having a 10 kohm impedance at 25° Celsius is used to sense the temperature of the laser diode. A regulated 5V supply source is provided through a 40 kohm resistor R11 and the thermistor TM1, resulting in a nominal 100 μA current through the thermistor TM1 and a voltage drop of approximately 1V across the thermistor TM1 at 25° Celsius. The thermistor is advantageously operated as part of a voltage divider circuit. The voltage drop across the thermistor TM1 changes with temperature and is sensed by op-amp U1A. The same 5V supply source is used to generate a 1V reference voltage using resistors R12, R34. This 1V reference source is sensed by op-amp U1B. In other words, the TEC control circuit compares temperature sensor voltage drop from the thermistor with a reference voltage, which corresponds to a voltage that would result if the thermistor were operated at a desired setpoint temperature. The difference between the output voltages of op-amps U1A and U1B is amplified by op-amp U1C. The output from op-amp U1C is the error signal associated with the desired temperature setpoint versus the actual laser temperature. The temperature setpoint in the embodiment depicted is 25° Celsius. Op-amp U1D and its associated resistors R45, R46 provide the error signal to the power FET U8 with the appropriate gate bias resistors R43, R44 and loop gain. The control signal to the power FET is integrated by resistor R47 and capacitor C8 to provide a gentle time constant so the current applied to the TEC is not impulsive. The time constant is preferably greater than 0.5 second, and more preferably approximately 1.0 second. Such a gentle time constant is desirable so that stress to the TEC is minimized, thus extending the life span of the TEC.
In a preferred embodiment utilizing TECs to cool the laser diodes, two TECs are coupled in series to cool a single laser diode. The TECs preferably comprise Melcor CPO 0.9-21-06 or similar devices. Such TECs operate at nearly optimum efficiency at 1.25 A and have an impedance of 2 ohms when operated at such a current. Thus, the total impedance of the two in series TECs is 4 ohms. When the maximum current of 1.25 A is drawn, approximately the full 5V supply voltage is dropped across the TECs, resulting in less than a 0.1V drop across the power FET U[0106] 8 under maximum cooling circumstances. In less demanding conditions requiring less cooling, the power FET U8 controls the current to the TECs by dropping some of the voltage across Vds. For example, when only 50% of the maximum current is required to cool the laser diode, the TECs draw approximately 0.63 A and drop 2.5V, with the remaining 2.5V appearing as Vds. Such circumstances represent a worst case scenario for dissipation in the controller, which is only 1.6 W. However, this worst case scenario occurs in cooler weather when the thermal stress on the overall system is reduced and the overall heat load can be more readily dissipated into the surrounding environment.
The above TEC controller circuit may be modified to use a 3.3 V supply source instead of a 5 V supply source. A 3.3 V supply source is more appropriate for less demanding cooling requirements. The TEC may also be modified to act as a both a cooling and heating element within the transceiver by proving a bipolar voltage supply source of +5V and −5V. [0107]
Notably, operation of a TEC as described above is not limited to controlling heat transfer from laser diodes. Instead, the TEC operation described above could apply to most any item that needs to be temperature-controlled. Operation of a power amplifier (preferably by way of a low voltage power source) as a controlled current source provides near-perfect efficiency when maximum cooling is required. When designing such a cooling system, the maximum cooling requirement of the item to be temperature controlled should be considered in light of the fact that a thermoelectric cooler has a characteristic impedance and an optimal operating current. The desired result may be achieved by selecting the optimal operating current of the thermoelectric cooler to correspond with the maximum cooling requirement of the item to be temperature controlled, and further selecting the impedance of the thermoelectric cooler to drop substantially all of the supply voltage when the thermoelectric cooler is operated to provide the maximum cooling requirement of the item. If maximum cooling efficiency is desired, then lower power supply voltages are preferable. [0108]
Accordingly, improved transceivers for transmission using laser signals originating in digital format are disclosed. Further disclosed are improved laser driver circuits capable of driving lasers with high frequencies and high currents, from either digital or analog input signals. Still further disclosed are methods and apparatus for operating a thermoelectric cooler with high efficiency, either with or without an accompanying laser diode. While embodiments and applications of this invention have been shown and described, it would be apparent to those skilled in the art that many more modifications are possible without departing from the inventive concepts herein. The invention, therefore, is not to be restricted except in the spirit of the appended claims. [0109]

Claims

What is claimed is:

1. A communication link for providing two-way communication through free space, the link including a first transceiver and a second transceiver, wherein at least one transceiver comprises:

an input signal interface for receiving a digital signal;

a splitter in communication with the input to split the digital signal into a plurality of approximately equal laser data signals;

a plurality of lasers displaced from one another and facing in parallel directions, each of the lasers being in communication with the splitter;

a plurality of laser drivers, each laser driver being coupled to one of the lasers and to the splitter, wherein the laser drivers receive the laser data signals and provide amplified laser data signals to the lasers at high power and high frequency.

2. The communication link of claim 1, wherein the input signal is characterized by a data rate of at least 10 Mbits/second, and each laser is supplied with a nominal current of at least 100 mA.

3. The communication link of claim 1, wherein said at least one transceiver further comprises an input signal regenerator in communication with the one or more digital input signals.

4. The communication link of claim 3, wherein the input signal regenerator includes a first clock and data recovery circuit which is switchable between one of a plurality of clock frequencies.

5. The communication link of claim 1, wherein each of the plurality of lasers includes a laser diode coupled to the laser driver and receiving the amplified laser data signals.

6. The communication link of claim 5, wherein each of the plurality of lasers further includes a lens for receiving and collimating the laser diode output into an optical beam.

7. The communication link of claim 6, wherein the beamwidth of the optical beam is adjustable.

8. The communication link of claim 7, wherein the beamwidth of the optical beam is adjustable between from 0.3 mrad to approximately 3.5 mrad.

9. The communication link of claim 6, wherein the beamwidth of the optical beam is less than 3.5 mrad.

10. The communication link of claim 5, wherein the laser driver includes a modulation signal amplifier coupled with the splitter and a DC bias circuit coupled between the modulation signal amplifier and the laser diode.

11. The communication link of claim 10, wherein the laser driver further includes a sampling photodiode, wherein the modulation signal amplifier is coupled with the sampling photodiode and responsive to the output of the sampling photodiode.

12. The communication link of claim 11, wherein the laser diode emits a laser beam, and the sampling photodiode monitors the power of the laser beam.

13. The communication link of claim 5, wherein said at least one transceiver further comprises a thermoelectric cooler in thermal communication with the laser diode.

14. The communication link of claim 5, wherein the laser driver operates at a current of between approximately 100 milliAmperes and 1500 milliAmperes.

15. The communication link of claim 5, wherein the laser diode generates an average power of at least 80 milliwatts.

16. The communication link of claim 1, wherein the digital signal a comprises packet-based communication signal in accordance with a data transmission protocol.

17. The communication link of claim 16, wherein the data transmission protocol complies with a protocol selected from the group consisting of TCP/IP, IPX, Fast Ethernet, SONET, and ATM.

18. The communication link of claim 1, wherein the transceiver is capable of operating on at least one layer selected from the group consisting of STS-3, STS-12, OC-3, and OC-12.

19. The communication link of claim 1 wherein said at least one transceiver further comprises:

an aperture;

a reflector in line with the aperture;

a photodiode at the focal point of the reflector; and

an output from the photodiode.

20. The communication link of claim 19, wherein the reflector has an f-number of about 0.67

21. The communication link of claim 19, wherein the reflector is a Mangin mirror.

22. The communication link of claim 19, wherein the reflector is a mirror having a general conic, aspheric, or parabolic optical surface that is coupled with one or more corrector lenses.

23. The communication link of claim 19, wherein said at least one laser transceiver further comprises a stray light baffle disposed across the primary aperture.

24. The communication link of claim 19, wherein said at least one transceiver further comprises:

a preamplifier coupled with the photodiode;

an output signal regenerator coupled with the preamplifier; and

an output signal interface coupled with the output signal regenerator.

25. The communication link of claim 24, wherein the output signal regenerator includes a second clock and data recovery circuit which is switchable between one of a plurality of clock frequencies.

26. The communication link of claim 19, wherein said at least one transceiver further comprises a background rejection filter near the focal point of the reflector.

27. The communication link of claim 26, wherein the background rejection filter is a bandpass filter.

28. The communication link of claim 26, wherein the background rejection filter is an optical interference filter and has a nominal center wavelength of approximately 1550 nanometers.

29. The communication link of claim 26, wherein said background rejection filter is a long wave pass filter having a threshold passage wavelength, said at least one transceiver further comprising a detector having a predictable responsivity roll-off at a wavelength above the threshold passage wavelength of the long wave pass filter.

30. The communication link of claim 19, further comprising a radio frequency backup transceiver.

31. The communication link of claim 30, wherein said at least one transceiver includes monitoring circuitry for monitoring signal strength or transceiver status.

32. The communication link of claim 31, wherein the backup transceiver is activated upon detecting impairment of the laser transceiver, and the backup transceiver is deactivated upon detecting non-impairment of the laser transceiver.

33. The communication link of claim 30, wherein said at least one laser transceiver operates with the backup transceiver in overflow mode.

34. The communication link of claim 1, wherein said at least one laser transceiver further comprises a protective enclosure.

35. The communication link of claim 34, wherein said at least one laser transceiver further comprises an environmental control system for maintaining a desired temperature and humidity within the enclosure.

36. The communication link of claim 1, wherein said at least one transceiver further includes a multiplexer to combine multiple signal inputs and a de-multiplexer to segregate multiple signal outputs.

37. A digital signal transceiver comprising:

an input signal interface for receiving a broadband digital signal;

a first regenerator coupled with the input signal interface;

a splitter coupled with the regenerator to split the digital signal into one or more laser data signals;

a high power, high frequency laser driver coupled with the splitter to condition the laser data signals; and

a plurality of lasers coupled with the laser driver to receive the laser data signals, the lasers being laterally displaced from one another and facing in parallel directions.

38. The transceiver of claim 56, wherein the first regenerator includes a first clock and data recovery circuit which is switchable between one of a plurality of clock frequencies.

39. The transceiver of claim 37, wherein each of the plurality of lasers includes a laser diode coupled to the laser driver and receiving the conditioned laser data signals.

40. The transceiver of claim 39, wherein each of the plurality of lasers further includes a lens for receiving and collimating the laser diode output into a beam having a beamwidth of 3.5 mrad or less.

41. The transceiver of claim 39, wherein the laser driver includes a modulation signal amplifier coupled with the splitter and a DC bias circuit coupled between the modulation signal amplifier and the laser diode.

42. The transceiver of claim 41, wherein the laser driver further includes a sampling photodiode, wherein the modulation signal amplifier is coupled with the sampling photodiode and responsive to the output of the sampling photodiode.

43. The transceiver of claim 42, wherein the laser diode emits a laser beam, and the sampling photodiode monitors the power of the laser beam.

44. The transceiver of claim 39, wherein the laser driver further includes a thermoelectric cooler adjacent to the laser diode.

45. The transceiver of claim 39, wherein the laser diode operates at a current of approximately between 100 milliAmperes and 1500 milliAmperes.

46. The transceiver of claim 39, wherein the laser diode generates an average power of at least 80 milliwatts.

47. The transceiver of claim 37, wherein the digital signal comprises packet-based communication signals in accordance with at least one data transmission protocol.

48. The transceiver of claim 47, wherein the at least one data transmission protocol complies with a protocol selected from the group consisting of TCP/IP, IPX, Fast Ethernet, SONET, and ATM.

49. The transceiver of claim 47, wherein the transceiver operates on at least one layer selected from the group consisting of STS-3, STS-12, OC-3, and OC-12.

50. The transceiver of claim 37, further comprising:

an aperture;

a reflector in line with the aperture;

a photodiode at the focal point of the reflector;

a preamplifier coupled with the photodiode;

a second regenerator coupled with the preamplifier; and

an output signal interface coupled with the second regenerator.

51. The transceiver of claim 50, wherein the reflector is selected from the group consisting of a Mangin mirror, a parabolic reflector coupled with a corrector lens, and a mirror having a general conic or aspheric optical surface and coupled with at least one corrector lens.

52. The transceiver of claim 50, wherein the second regenerator includes a second clock and data recovery circuit which is switchable between one of a plurality of clock frequencies.

53. The transceiver of claim 50 further comprising a background rejection filter disposed adjacent to the focal point of the reflector.

54. The transceiver of claim 53, wherein the background rejection filter is an optical hemispherical interference filter having a nominal center wavelength of approximately 1550 nanometers.

55. The transceiver of claim 50, wherein the reflector has an f-number of about 0.67.

56. An apparatus for efficiently driving a laser diode, the apparatus comprising:

a signal source providing an input signal;

a laser diode having a characteristic impedance; and

a power amplifier with a low output impedance suited to drive the laser diode;

wherein the power amplifier is operated as a voltage-controlled current driver for the laser diode.

57. The apparatus of claim 56, further comprising a voltage amplification stage between the signal source and the power amplifier.

58. The apparatus of claim 57, wherein the voltage amplification stage includes a non-linear limiting amplifier.

59. The apparatus of claim 56, wherein the power amplifier includes a broadband RF power field effect transistor.

60. The apparatus of claim 59, wherein the power field effect transistor is selected from the group consisting of MOSFET, silicon FET, and GaAs FET.

61. The apparatus of claim 59, wherein the broadband RF power field effect transistor is capable of operating at a minimum frequency of 1 MHz or less.

62. The apparatus of claim 56, wherein the broadband RF power field effect transistor is operated with a low supply voltage.

63. The apparatus of claim 56, wherein the supply voltage of the power amplifier is approximately equal to or less than 12 volts.

64. The apparatus of claim 56, wherein the supply voltage of the power amplifier is approximately 5 volts.

65. The apparatus of claim 56, wherein the power transistor provides output current of at least 100 mA to the laser diode.

66. The apparatus of claim 65, wherein the input signal is characterized by a data rate of at least 10 Mbits/second.

67. The apparatus of claim 65, wherein the input signal is characterized by a data rate of at least OC-3 bandwidth.

68. The apparatus of claim 56, wherein the power transistor provides output current of at least 200 mA to the laser diode.

69. The apparatus of claim 56, wherein the input signal is a signal selected from a group of protocols consisting of: TCP/IP, IPX, Fast Ethernet, SONET, and ATM

70. The apparatus of claim 56, wherein the laser diode has a characteristic dynamic impedance of between approximately 2 and 5 ohms.

71. The apparatus of claim 56, further comprising a thermoelectric cooler in thermal communication with the laser diode.

72. The apparatus of claim 56, wherein the laser diode is stabilized against temperature fluctuations.

73. The apparatus of claim 56, wherein the power amplifier is stabilized against supply voltage fluctuations.

74. The apparatus of claim 73, further comprising a zener diode for stabilizing power supply voltage against voltage fluctuations.

75. The apparatus of claim 56, further comprising an attenuator between the signal source and the power amplifier.

76. The apparatus of claim 75, wherein the attenuator is adjustable and is used to control the amplitude of the input signal to the power amplifier.

77. The apparatus of claim 56, further comprising:

a temperature sensor for sensing temperature of the laser diode,

a thermoelectric cooler in thermal communication with the laser diode, and

a thermoelectric cooler power amplifier,

wherein the thermoelectric cooler power amplifier is operated as a controlled current source to supply current to the thermoelectric cooler at near-perfect efficiency when maximum cooling is required.

78. The apparatus of claim 77, wherein the temperature sensor is a thermistor.

79. The apparatus of claim 78, wherein the voltage drop across the thermistor at a given temperature is compared to a reference voltage corresponding to the thermistor voltage when it is operated at a desired setpoint temperature.

80. The apparatus of claim 77, wherein the power amplifier is a power FET.