Programmable logic integrated circuit devices with low voltage differential signaling capabilities

Information

  • Patent Grant
  • 6236231
  • Patent Number
    6,236,231
  • Date Filed
    Friday, June 25, 1999
    25 years ago
  • Date Issued
    Tuesday, May 22, 2001
    23 years ago
Abstract
A programmable logic device is equipped for low voltage differential signaling (“LVDS”) by providing an LVDS input buffer and/or an LVDS output buffer on the device. I/O pins on the device that are used together in pairs for LVDS can alternatively be used individually for other types of signaling. The LVDS buffers are constructed to give good performance and to meet LVDS specifications despite variations due to temperature, manufacturing process inconsistency, and power supply changes.
Description




BACKGROUND OF THE INVENTION




A standard that has recently been developed for signaling over short distances is known as low voltage differential signaling (“LVDS”). A description of LVDS can be found, for example, in “LVDS Owner's Manual; Design Guide”, National Semiconductor, Spring 1997. (The reference mentioned in the preceding sentence is hereby incorporated by reference herein in its entirety.) Although LVDS is limited to distances of a few meters, this constraint is not a problem for use of this type of signaling between devices (e.g., integrated circuits) on a printed circuit board or in other relatively compact systems.




Because programmable logic devices (“PLDs”) such as are shown in Cliff et al. U.S. Pat. No. 5,689,195 and Jefferson et al. U.S. patent application Ser. No. 09/266,235, filed Mar. 10, 1999 are often desired as components of systems of the type for which LVDS is suitable, it would be desirable to provide PLDs with LVDS capabilities. (The references mentioned in the preceding sentence are hereby incorporated by reference herein in their entireties.) In addition, improvements are constantly being sought for LVDS circuitry generally, in terms, for example, of more uniform speed performance throughout the permitted operating voltage range, improved rejection of spurious signals, protection against open or short-circuited inputs, etc.




In view of the foregoing it is an object of this invention to provide improved circuitry for LVDS generally.




It is another object of this invention to provide PLDs with LVDS capabilities.




SUMMARY OF THE INVENTION




These and other objects of the invention are accomplished in accordance with the principles of one aspect of the invention by providing PLDs with input/output (“I/O”) pins that are connected in parallel to several different kinds of input and/or output buffers, including LVDS input and/or output buffers. The PLD is programmable to allow any of the input and/or output buffers to which an I/O pin is connected to be used. This allows the PLD to provide LVDS capabilities, if that is what is desired, without having to dedicate I/O pins to that particular type of use. Because an LVDS connection requires a pair of I/O pins, while many other signaling protocols require only one I/O pin per connection, the PLD circuitry is programmable to allow I/O pins to be used in pairs for LVDS or individually for other types of signaling.




To help make the speed of LVDS circuitry more uniform across the operating voltage range permitted by the LVDS standard, circuitry is provided for strengthening at least one of complementary current sources or sinks used in LVDS input buffers when the operating voltage is such that the circuitry associated with the other current source or sink is no longer able to help the input buffer operate. The thus-strengthened current source or sink helps to maintain the speed of the input buffer even though the circuitry associated with the other current source or sink is no longer operating effectively. Hysteresis circuitry may be provided in LVDS input buffers to help the buffer reject spurious input signal fluctuations. Pull-up connections may be provided on LVDS input signal leads to help protect an LVDS input buffer from producing erroneous output signals in response to open or short-circuit conditions on those input signal leads.




An LVDS output buffer in accordance with the invention is constructed to help keep the output voltages within the LVDS standard or specification despite variations due to such factors as (1) manufacturing process inconsistencies, (2) temperature changes, and (3) power supply voltage fluctuations. The LVDS output buffer includes differential output switching circuitry connected in series via resistors between power and ground potentials. One of the resistor circuits preferably includes a current source which tends to increase in resistance as the power supply potential increases, thereby helping to counteract the effect of increasing power supply voltage. The transistors in the differential output switching circuitry and the resistors in series with that circuitry are made so that they all have similar changes in resistance due to manufacturing process variations and temperature changes. This helps keep the LVDS output voltages within LVDS specifications despite these types of variations or changes. Capacitors are also preferably included in the LVDS output buffer to improve the performance of the circuitry in relation to switching transients.




Further features of the invention, its nature and various advantages will be more apparent from the accompanying drawings and the following detailed description of the preferred embodiments.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a simplified schematic block diagram of a representative portion of an illustrative embodiment of the invention.





FIG. 2

is a more detailed schematic diagram of an illustrative embodiment of circuitry that can be used for a portion of what is shown in

FIG. 1

in accordance with the invention.





FIG. 3

is a chart showing a representative operating condition of the

FIG. 2

circuitry.





FIG. 4

is a more detailed schematic diagram of an illustrative embodiment of circuitry that can be used for a portion of what is shown in

FIG. 2

in accordance with the invention.





FIG. 5

is similar to

FIG. 4

for another portion of what is shown in FIG.


2


.





FIG. 6

is a simplified schematic diagram of another representative portion of an illustrative embodiment of the invention.





FIG. 7

is a simplified schematic diagram of circuitry of the type shown in

FIG. 6

in conjunction with other circuitry, all in accordance with the invention.





FIG. 8

is a simplified schematic block diagram of possible modification of portions of earlier FIGS. in accordance with the invention.





FIG. 9

is a simplified schematic diagram showing possible combination of features from earlier FIGS. in accordance with the invention.





FIG. 10

is a simplified block diagram of an illustrative system employing a programmable logic device including LVDS capabilities in accordance with the invention.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS





FIG. 1

shows a small portion of a programmable logic device


10


constructed in accordance with this invention to include certain LVDS capabilities.

FIG. 1

shows the circuitry required to enable device


10


to receive LVDS signals. Circuitry for enabling device


10


to output LVDS signals will be shown in later FIGS. and described later in this specification.




As shown in

FIG. 1

, device


10


has I/O pins


20


. Although only two I/O pins


20


are shown in

FIG. 1

, it will be understood that these are only representative and that device


10


may have many more such pins. Each of depicted I/O pins


20


can be used separately as an input or output pin when LVDS input via the depicted pins is not desired. In that case, external resistor


30


would not be present. Each pin


20


could then receive an input signal from the associated external signal lead


40


, and that signal would be applied to the logic of device


10


via the associated conventional tri-state input buffer


50


. For example, the non-LVDS, single-conductor signaling being used could be transistor-transistor logic (“TTL”) signaling, and input buffers


50


would then be TTL buffers. Any other single-conductor (non-LVDS) signaling can be used with appropriate input buffers


50


. More than one type of input buffer


50


may be connected to each I/O pin


20


so that any of several single-conductor signaling protocols can be used. Each input buffer


50


is programmably controlled by an associated programmable function control element (“FCE”)


52


to be either on (i.e., able to drive an applied signal into the logic of device


10


) or tri-stated (i.e., off).




Each I/O pin


20


can be alternatively used as an output pin. In that event the associated tri-state output buffer


60


is enabled by its associated FCE


62


to apply a signal from the logic of device


10


to the associated I/O pin


20


, which applies that signal to the associated external conductor


40


. Again each output buffer


60


may be, for example, a TTL buffer or any other type of single-conductor signaling buffer, and several different types of such buffers may be associated with each pin


20


so that any of several different output signaling protocols can be used.




If it is desired to use depicted pins


20


together for input of LVDS signals, then all of FCEs


52


and


62


are programmed to disable the associated buffers


50


and


60


, and FCE


72


is programmed to enable LVDS input buffer


70


. Resistor


30


is also included across external leads


40


in accordance with LVDS standards. LVDS input buffer


70


is thereby enabled to convert LVDS input signals on leads


40


to single-conductor signals and to apply those signals to the logic of device


10


.




From the foregoing it will be seen that depicted I/O pins


20


can either be used individually for separate inputs or outputs (i.e., by using FCEs


52


or


62


to enable input or output buffers


50


or


60


, while using FCE


72


to disable buffer


70


), or the depicted pins


20


can be used together as a pair for LVDS input (i.e., by using FCEs


52


and


62


to disable all of buffers


50


and


60


, while using FCE


72


to enable buffer


70


).




Incidentally, it will be recognized that another term frequently used in the art for elements like buffers


50


,


60


, and


70


(and


600


in later FIGS.) is “drivers”, and the term “driver” may therefore sometimes be used herein as an alternative to “buffer.”




An illustrative embodiment of LVDS input buffer


70


is shown in more detail in FIG.


2


. Buffer


70


is turned on by programing FCE


72


to turn on current sink I


1


and current source I


2


. When buffer


70


is not to be used, FCE


72


is programmed to turn off elements I


1


and I


2


, thereby conserving power that would otherwise be consumed. Buffer


70


is constructed to be able to detect LVDS signals over the full range of permissible voltages according to LVDS standards. In particular, the offset voltage (“Voffset”) of the two LVDS input signals INA and INB in

FIG. 2

can be anywhere in the range from 0 volts to 2.4 volts when Vcc (power or logic 1 potential) for device


10


is 2.5 volts. Voffset is the average of the voltages of INA and INB. In order to operate satisfactorily over such a wide Voffset range, and especially at Voffset values that can be so close to Vss (ground or logic 0 potential) or Vcc, buffer


70


includes both an NMOS differential stage


100


and a PMOS differential stage


200


. The NMOS differential stage includes NMOS transistors


110


and


112


and operates except when Voffset is close to or below Vtn for NMOS transistors (i.e., the gate voltage required to turn on an NMOS transistor). Thus the NMOS stage stops operating or is partially turned off when Voffset is very close to ground potential. The PMOS differential stage includes PMOS transistors


210


and


212


and operates except when Voffset is above Vcc−Vtp (i.e., the voltage below which the gate of a PMOS transistor must be in order for that transistor to turn on). Thus the PMOS stage stops operating or is partially turned off when Voffset is close to Vcc.




Considering NMOS stage


100


in more detail, one LVDS input (INA) is applied to the gate of transistor


110


, and the other LVDS input (INB) is applied to the gate of transistor


112


. Current sink I


1


pulls current from the sources of both transistors


110


and


112


. (Although in the particular circuit relationship that it has in

FIG. 2

, element I


1


is perhaps most accurately described as a current sink, the more generic term for such an element is current source, and that term may sometimes be used herein as an alternative for current sink.) PMOS transistor


120


supplies current to the drain of transistor


110


. PMOS transistor


122


supplies current to the drain of transistor


112


. PMOS transistor


130


is a current mirror for transistor


120


. PMOS transistor


132


is a current mirror for transistor


122


. PMOS transistors


140


and


142


are relatively small transistors that increase the resistance of NMOS stage


100


to erroneous toggling in response to possible noise on LVDS signals INA and INB. In other words, transistors


140


and


142


help provide hysteresis in the response of NMOS stage


100


to the LVDS input.




PMOS stage


200


has elements that are functionally analogous to several of those described above for the NMOS stage. Current source I


2


supplies current to the sources of transistors


210


and


212


. INB is applied to the gate of transistor


210


and INA is applied to the gate of transistor


212


. NMOS transistor


220


conveys current from the drain of transistor


210


. NMOS transistor


222


conveys current from the drain of transistor


212


. NMOS transistors


240


and


242


provide hysteresis.




The combined differential outputs of NMOS stage


100


and PMOS stage


200


are applied to the gates of NMOS transistors


310


and


312


in the output stage


300


of buffer


70


. Output stage


300


converts the differential output signals to a single TTL output signal suitable for application to the logic of device


10


. Output stage PMOS transistor


320


supplies current to the drain of transistor


310


. Output stage PMOS transistor


322


supplies current to the drain of transistor


312


. The TTL output signal of buffer


70


comes from the drain of transistor


310


.




To illustrate the operation of the

FIG. 2

circuitry,

FIG. 3

shows the condition of various elements in

FIG. 2

when Voffset is in a middle range (i.e., not as low as Vtn or as high as Vcc−Vtp) and when INA is 100 millivolts higher than INB for LVDS transmission of a signal having a first polarity or logic value. (When INB is 100 millivolts higher than INA for LVDS transmission of a signal having a second polarity or logic value, all of the conditions shown in

FIG. 3

are reversed. For example, transistors shown as “partially on” in

FIG. 3

become “on”, and the associated transistors shown as “on” in

FIG. 3

become “partially on”. “On” transistors


320


and


322


in

FIG. 3

also become “partially on.”) As is at least implied by the earlier discussion, when Voffset becomes approximately Vcc−Vtp or higher, PMOS differential stage


200


ceases to operate, but NMOS stage


100


continues to perform well and provides the proper logic output on the right in FIG.


2


. Thus the LVDS input buffer circuitry shown in

FIG. 2

operates well over the entire Voffset required by the LVDS standard.





FIG. 2

also shows optional NMOS transistors


410


and


412


for respectively providing a weak pull down of leads INA and INB to ground. This is desirable for helping to prevent buffer


70


from producing spurious output signals in the event that leads INA and INB are open or shorted external to device


10


.




An especially preferred embodiment of current sink I


1


in

FIG. 2

is shown in

FIG. 4

, and a similarly preferred embodiment of current source I


2


in

FIG. 2

is shown in FIG.


5


. The current sink of

FIG. 4

has the advantage that as Voffset approaches and possibly exceeds Vcc−Vtp, the current drawn by the current sink increases. This increases the strength of NMOS differential stage


100


in

FIG. 2

as the strength of PMOS stage


200


is decreasing (or even becoming a load). In this way the speed performance of LVDS buffer


70


is kept relatively constant even when PMOS stage


200


ceases to contribute.




Considering

FIG. 4

now in more detail, the current sink circuitry of this FIG. is turned on by programming FCE


72


to turn off NMOS transistors


502


and


504


. Conversely, programming FCE


72


to turn on transistors


502


and


504


turns off the depicted current sink by clamping the gates of all of NMOS transistors


530


,


532


,


540


, and


542


to ground, thereby turning off all of those transistors. The following further discussion of the

FIG. 4

circuitry assumes that the current sink is turned on by turning off transistors


502


and


504


.




I


1


is the current drawn by element I


1


in FIG.


2


. Vref is a reference potential having a value which is approximately one-half of Vcc. Thus PMOS transistors


510


and


512


are on at all times. If INA and INB are higher than Vcc−Vtp, both of PMOS transistors


520


and


522


are off. This means that both of NMOS transistors


530


and


532


are off. (Transistors


530


and


532


are connected in a current mirroring configuration.) Because transistor


530


is off, all current from transistor


510


must flow through NMOS transistor


540


, which is on. NMOS transistor


542


is connected in a current mirroring configuration with transistor


540


. Because transistor


540


is strongly on, transistor


542


will be strongly on and current I


1


will be relatively large.




Values of INA and INB below Vcc−Vtp cause transistors


520


and


522


to turn on. This turns on transistors


530


and


532


. Transistor


530


“steals” some current from transistor


540


, thereby causing transistor


542


to reduce the amount of current I


1


.




From the foregoing it will be seen that when INA and INB are high enough to reduce or eliminate the contribution of PMOS differential stage


200


in

FIG. 2

, current I


1


is increased to increase the effectiveness of NMOS differential stage


100


. In this way, NMOS stage


100


can compensate for the loss of the PMOS stage


200


contribution and maintain the operating speed of LVDS buffer


70


. When INA and INB are not so high as to prevent PMOS stage


200


from contributing, current I


1


does not need to be so large and is accordingly reduced.




The embodiment of current source I


2


shown in

FIG. 5

is conceptually similar to what is shown in FIG.


4


. The

FIG. 5

circuit increases current I


2


when INA and INB are low (close to Vtn). This enables PMOS stage


200


in

FIG. 2

to operate more strongly when NMOS stage


100


is weak or unable to operate. The construction and operation of the

FIG. 5

circuit are so similar to the

FIG. 4

circuit that it is not believed necessary to describe

FIG. 5

in full detail. Analogous elements in

FIGS. 4 and 5

have reference numbers that differ by


50


. Thus element


510


in

FIG. 4

is analogous to element


560


in FIG.


5


. Inverter


73


inverts the output signal of FCE


72


for application to the gates of PMOS transistors


552


and


554


so that the

FIG. 5

current source is turned on or off by the same state of FCE


72


that turns the current sink of

FIG. 4

on or off, respectively.




Preferred LVDS output buffer circuitry


600


in accordance with the invention is shown in

FIG. 6. A

data signal (e.g., from logic circuitry (not shown, but typically conventional) on device


10


) is applied to output buffer circuitry


600


via inverter


602


. An LVDS output buffer enable signal (e.g., from a programmable FCE or from logic circuitry on device


10


) is applied to circuitry


600


via lead


604


. If the signal on lead


604


is a buffer-enabling signal (logic 1 in the depicted embodiment), NMOS transistor


606


is enabled to pass the data signal from inverter


602


. The signal on lead


604


is inverted by inverter


608


and passed by transistor


610


to be applied to one input terminal of each of NOR gates


630




a


and


630




b


. Assuming that the signal on lead


604


is logic 1, NOR gates


630




a


and


630




b


will be enabled by the resulting logic 0 inputs to pass (in inverted form) the signals applied to their other input terminals. The output signal of transistor


610


is inverted by two successive inverters


632


and


636


and applied to the gate of PMOS transistor


640


. (Transistor


634


is connected in level-restoring relationship to inverter


632


.) Again assuming that the signal on lead


604


is logic 1, the resulting logic 0 signal applied to the gate of transistor


640


turns on that transistor.




The data signal passed by transistor


606


(assuming that transistor


606


is turned on by the signal on lead


604


) is inverted by successive inverters


612


and


616


and by NOR gate


630




b


. (Transistor


614


is connected in level-restoring relationship to inverter


612


.) The data signal output by inverter


612


is also passed by transmission gate


620


(which has a delay approximately equal to the delay of inverter


616


) and inverted by NOR gate


630




a.






The output signal of NOR gate


630




a


is applied to the gates of NMOS transistors


650




a


and


652




a


. The output signal of NOR gate


630




b


is applied to the gates of NMOS transistors


650




b


and


652




b


. Accordingly, when the data signal applied to inverter


602


is logic 0, transistors


650




a


and


652




a


will be on and transistors


650




b


and


652




b


will be off. On the other hand, when the data signal applied to inverter


602


is logic 1, transistors


650




a


and


652




a


will be off and transistors


650




b


and


652




b


will be on. The upper one of I/O pins


20


in

FIG. 6

is connected between the source terminal of transistor


652




b


and the drain terminal of transistor


652




a


. The lower one of I/O pins


20


in

FIG. 6

is connected between the source terminal of transistor


650




a


and the drain terminal of transistor


650




b.






From the foregoing it will be seen that a logic 0 data signal applied to inverter


602


connects lower I/O pin


20


to Vccn via resistor


660




a


, transistor


640


, resistor


660




b


, and transistor


650




a


. (Vccn is a power supply voltage which may be higher than Vcc. For example, Vccn may be 3.3 volts or 2.5 volts when Vcc is 1.8 volts.) The same logic 0 data signal connects the upper I/O pin


20


to Vss via transistor


652




a


and resistor


660




c


. Accordingly, a logic 0 data signal causes current to flow from lower I/O pin


20


through the external LVDS circuit (including resistor


670


) to upper I/O pin


20


.




A logic 1 data signal applied to inverter


602


connects upper I/O pin


20


to Vccn via resistor


660




a


, transistor


640


, resistor


660




b


, and transistor


652




b


, and connects lower I/O pin


20


to Vss via transistor


650




b


and resistor


660




c


. Accordingly, a logic 1 data signal causes current to flow from upper I/O pin


20


through the external LVDS circuit (including resistor


670


) to lower I/O pin


20


. The network including transistors


650


and


652


therefore constitutes differential output switching circuitry configured to produce a pair of LVDS signals at terminals


20


in response to a single input signal applied to inverter


602


.




The circuitry that includes PMOS transistor


680




a


acts like a capacitor to help reduce possible voltage excursions of the node at the lower end of resistor


660




b


during transitions in the data signal applied to inverter


602


when all of transistors


650


and


652


may turn on briefly. The circuitry that includes PMOS transistor


680




b


similarly acts like a capacitor to help reduce possible voltage excursions of the node at the upper end of resistor


660




c


during transitions in the data signal applied to inverter


602


.




The LVDS output buffer construction shown in

FIG. 6

has several important advantages. In general, a circuit for supplying LVDS current through resistor


670


tends to exhibit current variations due to changes in (1) Vccn, (2) temperature, and (3) the process by which device


10


was manufactured. However, the LVDS specification has relatively narrow ranges for permissible output pin voltage difference Vod (250 to 450 millivolts) and Voffset (1.125 to 1.375 volts). The circuitry shown in

FIG. 6

is able to meet these output requirements despite variations of the types mentioned earlier in this paragraph.




The LVDS buffer shown in

FIG. 6

is constructed as a ratioed circuit including (1) NMOS output transistors


650


and


652


which perform the actual switching, (2) PMOS transistor


640


as a current source, (3) resistors


660




a


,


660




b


, and


660




c


to adjust the DC voltages at the output, and (4) capacitors


680




a


and


680




b


to aid in AC (alternating current or transient) performance. Output transistors


650


and


652


are sized so that their on-resistance is small compared to bias resistors


660




b


and


660




c


. Resistor


660




a


serves to increase the output resistance of PMOS transistor


640


, as well as providing for local series feedback so that when the power supply varies, the change in the current is not as great as it otherwise would be. Resistors


660




a


,


660




b


, and


660




c


are preferably all N-plus type to track any variations due to temperature or manufacturing process in NMOS output transistors


650


and


652


. The DC voltages at the output, as well as the standby current, are adjusted by adjusting the values of resistors


660




b


and


660




c


. The ratio between (1) the resistors


660




a


and


660




b


above transistors


650


and


652


and (2) the resistor


660




c


below those transistors determines the Voffset range. The total of these resistances (and resistor


670


) determines the range of Vod and thus the range of current through resistor


670


(which gives the differential signaling). Because the DC voltages and currents are set by the ratio of the resistors to the transistors, variations in process, temperature, and power supply voltages are rejected.




Capacitors


680




a


and


680




b


reduce charge-sharing effects when the output switches. The capacitors keep the nodes above and below output switching transistors


650


and


652


from drifting during switching and allow for faster rise and fall times, as well as overall speed improvement in the forward delay of the entire output driver.




A disable function is implemented by using NOR gates


630




a


and


630




b


. When disabled, all the output transistors are off, as well as the PMOS current source (i.e., transistor


640


). The disable control signal


604


can either be set by an FCE in device


10


, or it can be a logic signal routed out to driver


600


so that the user can have the option of enabling it.




An explanation of NMOS transistor


690


is as follows. All inverters, transistors, and NOR gates in

FIG. 6

(except inverters


602


and


608


) preferably use thick oxide. The reason for this is that these components may see a voltage level Vccn which is higher than Vcc. As has been mentioned, Vccn may be 3.3 volts or 2.5 volts when Vcc is 1.8 volts. The thick oxide protects the device integrity for reliability reasons (due to high voltage). A disadvantage of using thick oxide is that it slightly slows down the speed. Transistor


690


is added to speed up the logic path using a “look ahead” technique. When the output of inverter


602


switches from low to high, transistor


690


turns on and pulls down the input of inverter


616


, instead of waiting for the path that includes elements


606


and


612


to respond. When the output of inverter


602


switches from high to low, the “look ahead” does not exist. Transistor


690


simply turns off. The input of inverter


616


is pulled up only when the signal propagates via elements


606


and


612


. But usually the low-to-high transition is the worst case (i.e., the speed-limiting transition), and the “look ahead” feature improves performance for this case.





FIG. 7

shows circuitry in accordance with the invention for allowing the two I/O pins


20


that are used together with LVDS output buffer


600


to be alternatively used individually with conventional single-conductor input buffers


50


or conventional single-conductor output buffers


60


(similar to similarly numbered elements in earlier FIGS.). Buffer


600


has an associated FCE


601


(the output signal of which can produce the signal on lead


604


in FIG.


6


). FCE


601


is programmable by the user of device


10


to control whether or not LVDS output buffer


600


is enabled. Each of buffers


50


and


60


similarly has an associated FCE


52


or


62


programmable by the user to determine whether or not the associated buffer is enabled. If buffer


600


is enabled, then the I/O pins


20


shown in

FIG. 7

are used as a pair for LVDS, and all of the other buffers


50


and


60


associated with those pins are disabled. On the other hand, if buffer


600


is disabled, then any one of the other buffers


50


/


60


associated with each of the I/O pins shown in

FIG. 7

can be enabled to allow each pin to be used individually as either a conventional (single-conductor) output pin or a conventional (single-conductor) input pin.





FIG. 8

shows that the signal which selectively enables any of output buffers


60


or


600


can be a logical combination of the output signal of an FCE


62


or


601


and an output enable signal from the logic of device


10


. This logical combination is produced by logic gate


700


, which can be chosen to perform any desired logic function (e.g., a NOR function).





FIG. 9

shows that two I/O pins


20


can be used for either LVDS input (employing LVDS input buffer


70


), LVDS output (employing LVDS output buffer


600


), or conventional single-conductor input or output (employing buffers


50


/


60


). In effect,

FIG. 9

shows that the circuitry shown in

FIGS. 1 and 7

can be combined in relation to a given pair of I/O pins


20


.




Restating some of the foregoing in more generic terms, a programmable logic device


10


in accordance with the invention includes logic circuitry (“from logic”/“to logic” in

FIGS. 1

,


2


, and


6


-


9


) and a pair of interface terminals


20


for use in making connections to circuitry


30


/


40


/


670


that is external to the programmable logic device. The device further includes LVDS buffer circuitry


70


/


600


connected to both of the interface terminals


20


and configured to exchange with the interface terminals a pair of signals which are respectively associated with the pair of interface terminals and which differ from one another in voltage in order to represent information in accordance with an LVDS standard. The LVDS buffer circuitry may be an input buffer


70


configured to receive the pair of signals from interface terminals


20


and to produce a single output signal (“to logic”) indicative of the information for application to the logic circuitry of device


10


. Alternatively the LVDS buffer circuitry may be an output buffer


600


configured to receive from the logic circuitry (“from logic”) of device


10


a single input signal indicative of the information and to produce the pair of signals indicative of the information for application to interface terminals


20


.




Device


10


may also include programmable function control circuitry


72


/


601


configured to selectively enable the LVDS buffer circuitry


70


/


600


. Device


10


may further include single-conductor signaling buffer circuitry


50


/


60


connected to one of the interface terminals


20


and configured to exchange with the one of the interface terminals a single signal having voltages which represent data in accordance with a single-conductor signaling standard. Programmable function control circuitry


52


/


62


/


72


/


601


may be provided for selectively enabling either the LVDS buffer circuitry


70


/


600


or the single-conductor signaling buffer circuitry


50


/


60


while disabling remaining ones of the LVDS buffer circuitry


70


/


600


and the single-conductor signaling buffer circuitry


50


/


60


.





FIG. 10

illustrates a programmable logic device


10


of this invention in a data processing system


802


. Data processing system


802


may include one or more of the following components: a processor


804


; memory


806


; I/O circuitry


808


; and peripheral devices


810


. These components are coupled together by a system bus


820


and are populated on a circuit board


830


which is contained in an end-user system


840


.




System


802


can be used in a wide variety of applications, such as computer networking, data networking, instrumentation, video processing, digital signal processing, or any other application where the advantage of using programmable or reprogrammable logic is desirable. Programmable logic device


10


can be used to perform a variety of different logic functions. For example, programmable logic device


10


can be configured as a processor or controller that works in cooperation with processor


804


. Programmable logic device


10


may also be used as an arbiter for arbitrating access to a shared resource in system


802


. In yet another example, programmable logic device


10


can be configured as an interface between processor


804


and one of the other components in system


802


. It should be noted that system


802


is only exemplary, and that the true scope and spirit of the invention should be indicated by the following claims.




Various technologies can be used to implement programmable logic devices


10


providing the LVDS capabilities of this invention. For example, function control elements


52


/


62


/


72


/


601


and other FCEs can be SRAMs, DRAMs, first-in first-out (“FIFO”) memories, EPROMs, EEPROMS, function control registers (e.g., as in Wahlstrom U.S. Pat. No. 3,473,160), ferro-electric memories, fuses, antifuses, or the like. From the various examples mentioned above it will be seen that this invention is applicable to both one-time-only programmable and reprogrammable devices.




It will be understood that the foregoing is only illustrative of the principles of the invention, and that various modifications can be made by those skilled in the art without departing from the scope and spirit of the invention. For example, the numbers and types of other conventional input and output buffers


50


/


60


that can make alternative use of the I/O pins


20


associated with LVDS buffers


70


/


600


in accordance with the invention can be varied as desired.



Claims
  • 1. A programmable logic device having programmable logic circuitry comprising:a pair of interface terminals configured for use in making connections to circuitry that is external to the programmable logic device; and LVDS buffer circuitry connected to both of the interface terminals and configured to exchange with the interface terminals a pair of signals which are respectively associated with the pair of interface terminals and which differ from one another in voltage in order to represent information in accordance with an LVDS standard, wherein the LVDS buffer circuitry is further configured to receive the pair of signals and to produce a single output signal indicative of the information for application to the logic circuitry of the device.
  • 2. The device defined in claim 1 wherein the LVDS buffer circuitry comprises:a NMOS differential stage connected to the pair of interface terminals; a PMOS differential stage connected to the pair of interface terminals; and an output stage responsive to output signals of both the NMOS differential stage and the PMOS differential stage to produce the single output signal.
  • 3. The device defined in claim 2 wherein the NMOS differential stage comprises:circuitry configured to increase strength of the output signals of the NMOS differential stage in response to voltages on the pair of interface terminals that are high enough to interfere with operation of the PMOS differential stage.
  • 4. The device defined in claim 2 wherein the PMOS differential stage comprises:circuitry configured to increase strength of the output signals of the PMOS differential stage in response to voltages on the pair of interface terminals that are low enough to interfere with operation of the NMOS differential stage.
  • 5. A programmable logic device having programmable logic circuitry comprising:a pair of interface terminals configured for use in making connections to circuitry that is external to the programmable logic device; LVDS buffer circuitry connected to both of the interface terminals and configured to exchange with the interface terminals a pair of signals which are respectively associated with the pair of interface terminals and which differ from one another in voltage in order to represent information in accordance with an LVDS standard; and programmable function control circuitry configured to selectively enable the LVDS buffer circuitry.
  • 6. A programmable logic device having programmable logic circuitry comprising:a pair of interface terminals configured for use in making connections to circuitry that is external to the programmable logic device; LVDS buffer circuitry connected to both of the interface terminals and configured to exchange with the interface terminals a pair of signals which are respectively associated with the pair of interface terminals and which differ from one another in voltage in order to represent information in accordance with an LVDS standard; and single-conductor signaling buffer circuitry connected to one of the interface terminals and configured to exchange with the one of the interface terminals a single signal having voltages which represent data in accordance with a single-conductor signaling standard.
  • 7. The device defined in claim 6 further comprising:programmable function control circuitry configured to selectively enable either one of the LVDS buffer circuitry and the single-conductor signaling buffer circuitry while disabling a remaining one of the LVDS buffer circuitry and the single-conductor signaling buffer circuitry.
  • 8. A programmable logic device having programmable logic circuitry comprising:a pair of interface terminals configured for use in making connections to circuitry that is external to the programmable logic device; LVDS buffer circuitry connected to both of the interface terminals and configured to exchange with the interface terminals a pair of signals which are respectively associated with the pair of interface terminals and which differ from one another in voltage in order to represent information in accordance with an LVDS standard, wherein the LVDS buffer circuitry is further configured to receive from the logic circuitry of the device a single input signal indicative of the information and to produce the pair of signals indicative of the information for application to the interface terminals; and wherein the LVDS buffer circuitry comprises: a source of relatively high voltage; a source of relatively low voltage; differential output switching circuitry configured to produce the pair of signals in response to the single input signal; first resistor circuitry connected in series between the source of relatively high voltage and the differential output switching circuitry; and second resistor circuitry connected in series between the differential output switching circuitry and the source of relatively low voltage, connections between the sources, the differential output switching circuitry, and the first and second resistor circuitries being such that when the circuitry that is external to the device is connected to the interface terminals, current flows in series from the source of relatively high voltage through the first resistor circuitry, through the circuitry that is external to the device, through the second resistor circuitry, to the source of relatively low voltage.
  • 9. The device defined in claim 8 wherein transistors in the differential output switching circuitry and the first and second resistor circuitries are configured to have similar changes in resistance due to variations in a manufacturing process for making the device.
  • 10. The device defined in claim 8 wherein transistors in the differential output switching circuitry and the first and second resistor circuitries are configured to have similar changes in resistance due to changes in temperature of the device.
  • 11. The device defined in claim 8 further comprising:circuitry configured to turn off the differential output switching circuitry when it is not desired to use the interface terminals for LVDS.
  • 12. The device defined in claim 8 further comprising a capacitor connected in parallel with at least one of the first and second resistor circuitries.
  • 13. The device defined in claim 8 wherein at least one of the first and second resistor circuitries includes a transistor and is configured to increase in resistance in response to an increase in voltage difference between the source of relatively high voltage and the source of relatively low voltage.
  • 14. A digital processing system comprising:processing circuitry; a memory coupled to the processing circuitry; and a programmable logic device coupled to the processing circuitry and the memory, wherein the programmable logic device includes LVDS buffer circuitry connected to a pair of interface terminals and configured to exchange with the interface terminals a pair of signals which are respectively associated with the pair of interface terminals and which differ from one another in voltage in order to represent information in accordance with an LVDS standard.
  • 15. A printed circuit board comprising:a programmable logic device mounted on the printed circuit board and including programmable logic circuitry, a pair of interface terminals configured for use in making connections to circuitry that is external to the programmable logic device, and LVDS buffer circuitry connected to both of the interface terminals and configured to exchange with the interface terminals a pair of signals which are respectively associated with the pair of interface terminals and which differ from one another in voltage in order to represent information in accordance with an LVDS standard; and a memory mounted on the printed circuit board and coupled to the programmable logic device.
  • 16. A printed circuit board comprising:a programmable logic device mounted on the printed circuit board and including programmable logic circuitry, a pair of interface terminals configured for use in making connections to circuitry that is external to the programmable logic device, and LVDS buffer circuitry connected to both of the interface terminals and configured to exchange with the interface terminals a pair of signals which are respectively associated with the pair of interface terminals and which differ from one another in voltage in order to represent information in accordance with an LVDS standard; and processing circuitry mounted on the printed circuit board and coupled to the programmable logic device.
Parent Case Info

This application claims the benefit of the following provisional applications: No. 60/091,524, filed Jul 2, 1998; No. 60/115,213, filed Jan. 8, 1999; and No. 60/115,214, filed Jan. 8, 1999, all of which are hereby incorporated by reference herein in their entireties.

US Referenced Citations (4)
Number Name Date Kind
3473160 Wahlstrom Oct 1969
5067007 Kanji et al. Nov 1991
5689195 Cliff et al. Nov 1997
5939904 Fetterman et al. Aug 1999
Non-Patent Literature Citations (8)
Entry
“LVDS Owner's Manual; Design Guide”, National Semiconductor Corporation, Spring 1997, Chapter 1, pp. 1-7.
“Block Diagram for NSM LVDS Output Buffer”, “Circuit Trace from National Semiconductor Device”, National Semiconductor Corporation.
ORCA Series 3 Field-Programmable Gate Arrays, Preliminary Data Sheet, Rev. 01, Lucent Technologies Inc., Microelectronics Group, Allentown, PA, Aug. 1998, pp. 1-80.
Optimized Reconfigurable Cell Array (ORCA), Or3Cxxx/OR3Txxx Series Field-Programmable Gate Arrays, Preliminary Product Brief, Lucent Technolgies, Inc., Microelectronics Group, Allentown, PA, Nov. 1997, pp. 1-7 and unnumbered back cover.
“Using Phase Locked Loop (PLLs) in DL6035 Devices, Application Note”, Dyna Chip Corporation, Sunnyvale, CA, 1998, pp. i and 1-6.
“Using the Virtex Delay-Locked Loop, Application Note, XAPP132, Oct. 21, 1998 (Version 1.31)”, Xilinx Corporation, Oct. 21, 1998, pp. 1-14.
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Provisional Applications (3)
Number Date Country
60/091524 Jul 1998 US
60/115213 Jan 1999 US
60/115214 Jan 1999 US