NL1018499C2 - Telecommunications terminal for connecting households to external fiber optic network, has passive optical splitter and individual transmitter/receiver at intermediate fiber ends - Google Patents

Abstract

In conventional Passive Optical Networks (PON), the network signals are split using a passive optical splitter before being fed to signal converters at the subscriber's premises. The present terminal uses individual optical transmitter/receivers (14, 15,17,21) at each end of intermediate lengths of optical fiber (16,18).

Description

4

Fiber optic communication network for home connections

The present invention relates to a fiber optic communication network according to the preamble of claim 1.

Such a fiber optic communication network for house connections that provides an optical communication connection between one or more house connections and a network exchange uses a design that was developed around a decade ago and is known as Passive Optical Network (PON). In a PON, on the network exchange side, the signals intended for different home connections are multiplexed and sent to an optical splitter via a single optical connection (fiber optic). The optical splitter serves to split the multiplexed signals into the individual signals for each home connection separately. The optical splitter is placed in the vicinity of the housing connections, so that the majority of the distance between the network exchange and a housing connection is bridged by the single optical connection. Separate (relatively short) fiber optic connections are provided from the optical splitter 15, each of which leads to a home connection.

The same PON is used for sending signals from the home connection to the network exchange, the optical splitter having the option of multiplexing signals from the home connections and forwarding them to the network exchange. In the network exchange, the signals incoming from the house connections are again demultiplexed.

The PON design outlined above, in which all signals are sent over a single fiber optic, arises from the (then) idea to keep the high costs for optical connections as low as possible by sharing the use of the single fiber optic with as many house connections as possible.

A disadvantage of the above-mentioned PON is the signal loss that occurs by splitting signals in the optical splitter (and / or the network exchange). The optical signal that is split is attenuated during that operation. In a known PON, this disadvantage is eliminated by first optically splitting the multiplexed signal entering the splitter, and then by applying a signal converter to convert the optical signal by an optical receiver into an electrical signal, this electrical signal to amplify and demultiplex, and again convert the demultiplexed signal with the aid of an optical signal source into an optical signal which is forwarded to the relevant housing connection. However, this signal conversion solution has the disadvantage that an optical signal source with high power (for example a laser) and an optical receiver with high sensitivity are required in the optical splitter per house connection. Such equipment requires large investments, all the more since every home connection requires such equipment in both the optical splitter and the network exchange.

It is an object of the present invention to provide a fiber optic communication network for home connections that is simpler in structure.

In order to achieve this goal, the present invention provides a fiber optic communication network of the type mentioned in the preamble, characterized in that the optical transceiver comprises an optical transmitter and an optical receiver, the optical transmitter using analog signals for transmitting digital 15 optical signals, and the optical receiver generates analog signals from received digital optical signals; the optical transmitter comprises a light-emitting diode for transmitting digital optical signals; and the optical receiver comprises a photodiode for receiving digital optical signals.

A fiber optic communication network according to the present invention has the advantage that the complex conversion of a signal from the optical domain to the electrical domain, and after amplification, again from the electrical to the optical domain, can be omitted.

Furthermore, the fiber optic communication network according to the present invention has the advantage that such a fiber optic communication network has only small signal losses between the network exchange and the house connections.

A further advantage is that in a fiber optic communication network according to the present invention, the communication speed is only limited by the cut-off frequency of the optical transmitters and receivers, so that data transmission speeds above those of the known ADSL network connections are thereby possible.

1018499tf 3

The invention will be explained in more detail below with reference to a few drawings, in which exemplary embodiments thereof are shown. They are intended solely for illustrative purposes and not to limit the inventive concept, which is defined by the claims.

5 Show

FIG. 1 schematically a fiber optic communication network designed as a passive optical network according to the state of the art;

FIG. 2 schematically an embodiment of a fiber optic communication network according to the present invention; FIG. 3 is an electrical diagram of an embodiment of an optical transmitter for use in the fiber optic communication network according to the present invention; and

FIG. 4 is an electrical diagram of an embodiment of an optical receiver for use in the fiber optic communication network of the present invention.

Figure 1 shows schematically a fiber optic communication network designed as a Passive Optical Network according to the prior art.

The fiber optic communication network 1 comprises a network exchange 2, a single common optical connection 4, an optical splitter 5, a first and second signal converter 8, 11 and a large number of house connections iN (of which only two house connections become 3.12 shown).

In the network exchange 2 network connections 6, 7 for house connections i..N are connected via first signal converter 8 to the common optical connection 4. Via optical splitter 5 the common optical connection 4 is connected to the individual fiber optic connections 9,10 for house connections 25 in. In each individual fiber optic connection 9,10 a second signal converter 11 is included which is connected to a communication interface of the corresponding housing connection iN. The communication interface serves as a link for data communication means from the home connection to the fiber optic communication network 1. In Figure 1, this communication interface for home connection 3 is schematically represented by the arrows D3. This communication interface D3 serves for connecting to communication equipment associated with the home connection 3, such as telecommuting and data communication equipment, computers, etc.

1018499 * 4

Signals for the house connections i..N are provided to the network central unit 2 via corresponding individual network connections 6, 7. The network connections 6, 7 are connected to other (data) communication networks such as, for example, a PSTN, ISDN, LAN or WAN network. The signals from these network connections 6, 7 are multiplexed in the first signal converter 8, (optionally) converted from the electrical domain to the optical domain and thereby possibly amplified, and then transmitted via the common optical connection 4 to the optical splitter 5 .

In the optical splitter 5, the signal from common optical connection 4 is split into a number of identical signals for each housing connection individually.

At this split, signal weakening occurs. As is known to the person skilled in the art, when a signal is split into 2 n identical signals, where n is the number of housing connections i .. N, the attenuation of the optical splitter 5 is 3.5 x n dB. For 32 connections, ie n = 5, the attenuation of the split signal relative to the incoming signal is therefore 17.5 dB. Because such a signal attenuation is undesirable in the transmission over the individual fiber optic connection 9, 10, the attenuated signal in each of the individual fiber optic connections 9, 10 of each housing connection in the second signal converter 11 connected thereto is processed as follows: optically to the electrical domain, amplification, demultiplexing and converting the electrical to the optical domain. The signal is then forwarded to the home connection via the associated communication interface D3.

When transmitting signals from a home connection 3, the same processing takes place: the signal is applied via communication interface D3 and second signal converter 11 to optical splitter 5, which supplies the signal to the common optical connection 4. In the first signal converter 8, demultiplexing and possibly amplifying the received signal takes place, whereafter the demultiplexed signal is applied from the network exchange 2 to the network connection 6, 7, which belongs to the house connection 3 which generated the original signal.

In the fiber optic communication network 1 according to the prior art, relatively large power is required in the signal converter 8, 11 for generating optical signals of sufficient intensity, so that the signals are still detectable after the attenuation in the optical splitter 5. A relatively high detection sensitivity is required in the signal converter 8, 11 in order to be able to still detect optical signals after attenuation.

Figure 2 schematically shows a fiber optic communication network according to the present invention. In this Figure 2, reference numerals similar to those of Figure 1 serve as reference to the same units as in Figure 1.

Figure 2 shows a fiber optic communication network 100 according to the present invention. This fiber optic communication network 100 comprises a network exchange 2, a large number of separate optical connections 16, 18 for house connections i .. N, and house connections i .. N, two of which house connections 19, 20 are shown. As is known to those skilled in the art, the optical signals transmitted via the fiber optic communication network 100 are digital signals.

The network exchange 2 is connected to each home connection iNN 19.20 via a corresponding separate single optical connection 16,18. The network exchange 2 comprises a large number of network connections i..N 6, 7 corresponding to the number of house connections i..N. For each of these network connections 1, 6, 7, the network exchange 2 comprises an optical transceiver 14,15. Of the network connections 6, 7, housing connections 19, 20, individual single optical connections 16, 18 and optical transceivers 14, 15 present in the network, only two of each are shown in Figure 2.

The housing connections 19, 20 are each connected by means of an optical transceiver 17, 21 to the corresponding individual single optical connections 16, 18. The optical transceiver 17 serves for transmitting and receiving optical signals via the corresponding individual single optical connection 16, 18. From the optical transceiver 17, 21 in each separate home connection 19,20 there is a connection to a corresponding communication interface D1, 9, D20.

In the network exchange 2, signals for the corresponding house connections i..N are provided via network connections i..N 6, 7. The (digital) signals of these network connections 6, 7 are transmitted in the corresponding optical transceiver 14, 15 via the corresponding individual single optical connection 16, 18 to the optical transceiver 17, 21 of the associated 10184990 6 home connection 19, 20. Optionally, when the signals from the network connection 6, 7 are (digital) electrical signals, they are converted from the electrical domain to the optical domain and thereby possibly amplified before the signals are transmitted via optical connection 16, 18.

In the optical transceiver 17, 21 of the home connection, the signals from the optical domain are converted to the electrical domain and passed on to the corresponding communication interface D19, D20. Optionally, the signals are passed to the communication interface D19, D20 as optical signals. The signals in the optical transceiver 17, 21 can be amplified here.

An important advantage of this fiber optic communication network 100 according to the present invention is that expensive and complex multiplexer / demultiplexer shown in Figure 1, which is required in the state of the art on the part of both the network exchange 2 and the house connections . Also, as in the prior art, the need to amplify the signal after passing through the optical splitter 5 is absent here. Although some signal loss occurs in the individual single optical connections 16, 18, this is relatively only small: with an average length of the single optical connection 16, 18 of 5 km and a weakening of 0.5 dB / km, only a 2.5 dB loss. In comparison, the loss that occurs in a fiber optic communication network, as shown in Figure 1, for 32 home connections and a fiber length of 5 km is approximately 20 dB.

The transceiver 14,15,17,21 comprises an optical transmitter and an optical receiver which are both connected to the single optical connection 16,18. In view of the condition outlined above with regard to the small occurring signal losses, in the present invention the optical transmitter and the optical receiver can be designed as simple analog circuits.

Furthermore, the low signal loss in the individual single optical connections has the consequence that the requirements for the optical transmitter and the optical receiver with respect to the power for generating an optical signal and the detection sensitivity for an optical signal are less heavy than for the signal converter 8,11 as used in the prior art. In the present invention, the optical transmitter 40 requires only a small power to generate a usable signal. The transceiver 14, 15, 17, 21 may also be provided with a receiver with a relatively lower detection sensitivity than a signal converter 8, 11, since the range within which the intensity of the transmitted signals is located is limited to approximately 2 , 5 dB.

Figure 3 shows an electrical diagram of an embodiment of an optical transmitter 5 for use in the fiber optic communication network according to the present invention. The optical transmitter 40 according to this embodiment comprises a light-emitting (laser) diode LED, a first transistor T1 and a second transistor T2 in the circuit. Furthermore, the circuit comprises a number of passive elements such as capacitor C1, and resistors R1, R2, R3 and R4. The structure of the circuit is shown in Figure 3.

The electrical input signal Vin, which is a representation of the digital signal to be transmitted, is supplied to the circuit on port 41. At port 42, the supply voltage Vcc is applied. The circuit is connected to ground via port 43.

In the circuit, the first transistor T1 serves as a buffer for the input signal. The second transistor T2 converts the input signal into a current that modulates the LED current. The light signal 44 thereby generated in the LED is supplied to the single optical connection 16, 18.

Figure 4 shows an electrical diagram of an embodiment of an optical receiver for use in the fiber optic communication network according to the present invention.

The optical receiver 50 according to this embodiment comprises a photodiode 51 in the circuit and a third transistor T3. The circuit further comprises a number of passive elements such as capacitors C2, C3, and resistors R5, R6, R7 and R8. The construction of the circuit is shown in Figure 4.

The photodiode 51 is optically connected to the single optical connection 16, 18. An optical signal 45 which the photodiode 51 receives via the optical connection 16,18 is converted into an electrical signal which is applied to third transistor T3. In the embodiment shown, transistor T3 is preferably a high impedance field effect transistor 30 (in the figure: S: source, D: drain, G; gate). Transistor T3 buffers and amplifies the electrical signal from the photodiode 51, and outputs the amplified signal through port 53 as an electrical voltage Vout · Electrical 1018499 «8 voltage Vout is a representation of the optical (digital) signal from single optical connection 16.18.

The circuit further comprises a gate 54 to which the supply voltage Vcc is applied. The circuit is connected to earth via port 52.

The optical transmitter 40 and the optical receiver 50 form part of an optical transceiver 14, 15, 17, 21 which is used in the fiber optic communication network 100 according to the present invention. As shown, the circuits 40, 50 according to the embodiments are relatively simple, but as stated above, it is sufficient to send digital signals via the single optical connections 16, 18. The maximum frequency bandwidth within which signals can be sent is determined by the cut-off frequencies of the circuits 40, 50. A bandwidth for data transmission of about 40 to at least 200 Mbit / s is possible in the fiber optic communication network 100 when circuits 40, 50 are used.

Finally, it is noted that in a fiber optic communication network 100 according to the present invention no management facility is required in the connection between network exchange 2 and house connection 19, 20, such as in the network according to the prior art, for data from different house connections separated from each other , to be sequentially transmitted serially over the common optical connection 4.

In optical fiber communication network 100, the optical communication is separated into the network exchange 2. Hereby, the optical fiber communication network 100 according to the present invention is simpler and less expensive.

1018499 «

Claims (1)

A fiber optic communication network for communication between a network exchange and at least two home connections by means of digital optical signals, wherein - the fiber optic communication network (100) between the network exchange (2) and each of the at least two home connections (19,20) a separate single optical connection (16,18), the network exchange (2) comprises a first optical transceiver (14,15) for transmitting and receiving digital optical signals in the separate single optical connection to each of the at least two home connections (19,20 each of the at least two housing connections (19, 20) comprises a further optical transceiver (17, 21) for transmitting and receiving digital optical signals in the separate single optical connection to the network exchange (2); Characterized in that the optical transceiver (14, 15, 17, 21) comprises an optical transmitter (40) and an optical receiver (50), wherein the optical transmitter (40) uses analog signals (Vi ') for transmitting of digital optical signals, and the optical receiver (50) generates analog signals 20 (Vout) from received digital optical signals; the optical transmitter comprises a light-emitting diode (LED) for transmitting digital optical signals; and the optical receiver comprises a photodiode (51) for receiving digital optical signals. 1018499 «