FI116925B - Optical data receiver and method for detecting optical data pulses and for generating signals representing these data pulses - Google Patents

Description

Optical Data Traffic Receiver and Method for Optical Data Semitization and Generation of Signal Equivalents - Learn the Optical Data Transmitter and the Signal Detector

The present invention relates to optical data traffic receivers, and not exclusively, to optical data traffic receivers that are operative to detect c representative light pulses.

Data can be transmitted in the form of light pulses between the optical transmitter and the 10 receivers. Transmitting data in this way provides a means to isolate the hardware associated with the da data receiver.

It is often required that commercial equipment produced by one manufacturer be interchangeable with equipment manufactured by another manufacturer in the event that data is transmitted in the form of light pulses, but may vary widely in the duration and intensity of such light pulses in the equipment produced. In addition, there may be other factors that determine the duration of light pulses to be detected by the optical receiver; six have significant variations. The optical receiver is provided by: Λ: it is capable of detecting pulses with significant temporal width and power, while minimizing complexity and op: Y costs, a technical problem.

• 1. . The technical problem of the expression I · «having a significant variation in temporal width and intensity is answered by the receiver of the present invention.

· 1; According to the present invention, an optical data receiver is provided «V1 1 i. ···. the light detector which operates on the light lenses it receives represents a comparator 2 having a first input coupled to a pulse expander input pulse amplitude scaled, wherein the comparator is provided with an output signal pulse when said extended pulse signal is greater than said detection threshold.

5 Some light pulses detected by the light detector may be more significant than other pulses. The pulse expander may be used to time the short-duration pulses of such expressions so that a predetermined minimum length of electro pulse signal is detected for the representative light pulses. In addition, light pulses can change the c 10 energy and hence the intensity. The rigors of such things can per se vary. However, this variation occurs over a proportional time interval, whereby the amplitude of the pulses does not change by any significant amount. Therefore, the average peak pulse detected by the light detector of the peak amplitude scatter threshold can be used, depending on 15 d. When this average amplitude is scaled according to a predetermined level, pulses can be formed. By supplying the stretched pulses and the threshold to the other input of the comparator e, the optical receiver is provided with means for data pulse * representing optical data without the need for a relatively fast comparator circuit.

# »• 9 Λ * * / As used herein, the term light shall mean and include light in the invisible part of the spectrum.

9 9 Ψ nop ** ** ** ** ** ** ** **: The optical receiver may further include a fast recovery amplifier connected between said light detector and said pulse expander and «25 amplitude scaled and amplified to amplify electrical pulse signals from the ion detector. Fast recovery £. ^ additionally arranges for a rapid recovery from the saturation state caused by the high amplitude pulses received by the light detectors • Λ 3 - averaging the amplitudes of the detected signal pulses, r averaging the amplitude, - generating the average of the tasting signal pulses and comparing and - generating, by comparison, an output signal which represents the manifestations.

The optical data receiver and method according to the invention are characterized in what is disclosed in the independent claims.

An embodiment of the present invention will now be described, by way of example and with reference to the accompanying drawings, in which Fig. 1 is a simplified block diagram of an optical data receiver circuit, a first circuit diagram of an optical receiver circuit shown in Fig. 1;

Detector a a '* defined by the IrDA (Infra-red Data Association) systems have become a de facto standard in communications with â € œ pulses. According to this standard, the communication is arranged: V: 20 by receiving infrared pulses. Definition of Inner Layer Specification for IrDA Serial Infra: · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · ·. the red pulse receiver shall detect pulses of le μβ with a magnitude of 4 to 500,000 μλν / cin. This applies up to da kbit / s. Such optical receivers must also be durable. ^ 25 other stray radiation that the detector may receive. The in: j: receiver must be imitated to form a puli * · 4 shaped circuit of a certain shape, and is also arranged to perform substantially better than known optical receivers.

In Fig. 1, the light detector 1 is mimicked to receive a light pulse line 2 and transmitted by a suitable communication means such as a fast recovery amplifier 3 connected to the Vale 5 mascot 1. The pulse expander 4 and pulse amplitude ί have a plug! rin 6 to the first and second inputs, respectively. A comparator 6c to distribute the output conductor 8.

During operation, the light detector 1 receives an infrared light pi, generating electrical pulse signals to the conductor 10, which is accompanied by a description of the temporal length and intensity of the copper crab pulses. The line 10 is electrically energized to a fast recovery amplifier 3. Generally, the amplifier 3 operates to amplify the electrical pulse signals that emit infrared pulses received from the maize 1. In addition, a fast capture path is followed to amplify electrical pulse signals in a significant area. This is accomplished by providing fast recovery with them so that it can recover after receiving the electrical signal pulse d1 large enough to drive the amplifier to saturation. Confirmed: 20 tracked to recover quickly from saturation mode, following * amplifies and transmits to pulse expander 4 and pulse amplitude <• · • t * • · · *: * ·; The light detector 1 produces amplified representations of infrared pulses: Vs, which are fed by wire 10 to pulse expander 4 and pulse a * m 25 to dilute 5. Pulse expander 4 operates by selectively increasing the width of each so that all pulses introduced by pulse expander lal; at a predetermined time interval in mm. The pulse expander 9 * 1 ** 1 / therefore considered to act as a short time constant integrator pu 5 can be used to determine whether a pulse is detected. This expression 1 is detected at the output of the pulse amplitude scaling 5 as a threshold value to the second input of the parator 6. Therefore, the detection threshold is a long-term function of the number of pulses. The threshold applied to the second input of the full 5 parator 6 represents its flux for pulse detection. The comparator 6 receives no output from the pulse expander 4. If the pulse expander 4 conveys a predetermined minimum time width and is greater than a threshold, the comparator 6 is therefore disposed to form a conductor 10 with a predetermined width and amplitude sufficient to control the next stage of the apparatus. In the arrangement of the pulse expander 4 and the pulse amplitude 5, they interact in such a way that the fast and the din pulses have substantially the same potential to come with longer pulses of larger amplitude. The 15 probability of expressing the result is that the pulse detector: uses a less sensitive and hence cheaper comparator 6. the receiver can be configured to operate with components with back response times, thus providing a significant power

The diagrams in Figures 2 and 3 illustrate an embodiment where the embodiment 20 is implemented, whereby the parts shown in Figure 1 also have the same reference: It is shown that the light detector 1 comprises a photodiode D1 and a diode D1 is imaged for use in photovoltaic mode, where it is connected to an amplifier and provided with a low value or parallel arrangement provides a fast response time and substantial day of inactivity,. p. e. 25 radiation, without causing significant leakage current. In the picture t ·>

how the light detector 1 is coupled to the fast response1 v * the fast response amplifier 3 comprises five transistors T1, T2, T

is traced to provide a pulse: twitch detected by the light detector 1, and which supplies an electrical pulse signal of the optical pulses k * * * * ϊ τπαΙΙα TrancictArpiHpn ΤΊ Τ ') T9 TΛ ImllAlrtrits is the IrirttAthr nncv 6 amplitude of the amplitude , whose collector is connected to positive Vcc and whose emitter is connected via resistors R12, R13 and kon to earth conductor GND. The emitter of transistor T6 is coupled via con 5 and R14 to the comparator 22r forming the comparator 6. The pulse amplitude scaler 5 is shown to comprise a collector connected to a positive supply voltage Vcc j; is connected to ground through resistor R15 and capacitor C6. The terminals of the transistor T6 are coupled to a terminal 24 which, during operation, is 10 to 20 and is arranged to receive an electrical pulse signal from the amplifier 3. The pulse expander and bias circuit of the pulse amplitude scale are shown to comprise a resistor T8 already coupled to a ground R16 and whose collector is via resistor R17 to terminal 24. Comparator 22 has a positive 15 pulse amplitude scaler 5 output at resistor R15 and a condensate point via resistor R18. The resistors R19 and R20 form a resistor R21 with the resistor R21 guarding the comparator 6. The switching capacitors C7, C8, Cl1 form the circuit of Figure 3. Comparator 22 is sequenced to form a defined amplitude and temporal width of Ia 20, and occurs at the output: As will be understood by one skilled in the art, various modifications will be made herein without departing from the scope of the present invention.

For example, the invention may be applied to the detection of any »». [.1: pulses representing data to be transmitted, and may also be +. . 25 types of electromagnetic radiation such as microwave radio signals. l.l for retrieved data.

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Claims (4)

An optical data receiver, comprising a light detector (1), which: generates electrical pulse signals representing the light pulses of a pulse expander (4) coupled to said light detector and to receive said electrical pulse signals and to selectively increase the temporal length of said pulse signals , so that the similarly expanded electrics have a predetermined minimum time duration, characterized in that the tamper receiver further comprises a scalar (5) for the amplitude of the pulse by forming a detection threshold on the basis of the amplitude of the electrical pulse signals received from the light detector and a scaling threshold; and a comparator (6), whose first input is a cup,. The amplifier (4) and other inputs to the scalar (5) of the pulse amplitude, are arranged to form an output pulse of said expanded pulse amplitude which is greater than said detection threshold. «I · 4 4 4 I ♦ * I · ** ·; Optical data receiver according to claim 1, characterized in that, y. further receivers include a storage amplifier (3) which; Of said photodetector (1) and said pulse expander (4) and proximity to said pulse amplitude, and which are arranged to amplify the electrics coming from said photodetector (1). «% · 4 4 4 444 4 444 __ 9 A method for detecting optical data pulses and for generating those data pulses, wherein in the method: - signal pulses representing the optical data pulses are generated by the photodetector and - selectively expand the length of the signal pulse such that each signal pulse has a tuned minimum time duration, characterized by the method further comprises the stages in which: - the average of the amplitude of the detected signal pulses is poured an average amplitude, - the average amplitude is scaled to generate a portion of the base of the signal pulses to be detected and the threshold of the amplified signal pulses is compared, and - is generated. according to the comparison, an output signal representing the data pulses. • 1 «· · • 1 • · • · · · · · · · · · · · · · · · · · · · · 9 · · a · · # · · ♦ · · * ·· · ·