FR2917558A1 - Camera's LED flash unit managing method for e.g. mobile telephone, involves carrying out activation of signal, deactivation of unit, transmission and reception of packets and reactivation of unit to inhibit unit during packet transmission - Google Patents

Abstract

The method involves activating a transmission signal before transmission of data packets and deactivating an LED flash unit of a camera if the flash unit is active. The data packets are transmitted and received for allocated temporal segments. The flash unit is reactivated when the data packets are transmitted. The activation of the signal, deactivation of the flash unit, transmission and reception of the data packets and reactivation of the flash unit are carried out for inhibiting the flash unit during transmission of the data packets. An independent claim is also included for a radio communication terminal comprising a transmitting and receiving unit.

Description

The present invention relates to a flash management method of a

  camera integrated in a wireless communication terminal. It is more particularly the management of the power supply when using the flash concomitantly with a radio transmission.

  Wireless communication terminals, for example mobile telephone terminals, are generally powered by a battery. The electric energy resource is therefore limited. They have to communicate by radio with usually a base station that is typically a few hundred meters away, or even a few kilometers away. The transmissions are consequently greedy in electrical energy. In addition, the integration of a camera in these devices has become general today. Generally, these cameras built into wireless communication terminals do not have a flash unit to illuminate the scene when shooting. Indeed, the operation of a conventional flash unit based on the use of a xenon discharge lamp involves charging a high value capacity. The electrical energy, thus stored in the capacitor, is then discharged rapidly through the lamp to cause the flash of light during the shooting. Such discharge lamps are also greedy energy. Their use in wireless communication terminals tends to significantly reduce the autonomy of the latter. However, such terminals still exist. In this case, it is generally implemented a mechanism to prevent the load capacity that typically lasts several seconds and the communication module operate simultaneously.

  A new type of camera flash unit appeared. These new units are based on the use of light-emitting diodes (LEDs) as a light source. These new units do not work by discharge like the traditional units with xenon lamp, but by direct supply. They are less greedy in energy but still consume a quantity of current of the same order of magnitude as the communication module. This amount of current is directly related to the power of the flash unit. The higher this power, the better the images taken in poor lighting conditions.

  Furthermore the integration of such a flash unit in a wireless communication terminal poses the problem of managing the energy to be shared between the radio communication module and the flash unit. The invention aims to solve the above problems by proposing a management method of the flash unit integrated into a wireless communication terminal allowing micro-cuts of the supply of the flash unit during the radio transmission of a communication frame. In this way, the concomitant power supply of the flash unit and the transmitting radio module is avoided. This result is achieved without prohibiting communication when shooting using the flash unit.

  The present invention relates to a method for managing a flash unit within a radio communication terminal equipped with shooting capabilities, the communication being done by receiving and transmitting data packets during allocated time slots, characterized in that it comprises a step of inhibiting the flash when transmitting a data packet.

  According to a particular embodiment of the invention, the flash unit can be used in several modes involving different current consumption, the flash inhibition step is performed in some of these modes. According to a particular embodiment of the invention, said inhibition step comprises a step of activating a transmission signal prior to transmission of the data packet; a step of inactivation of the flash if it is active; a step of transmitting the data packet and a step of reactivating the flash when the data packet is transmitted. The present invention also relates to a radio communication terminal comprising means for transmitting and receiving data packets during allocated time slots; shooting means; a flash unit and means for inhibiting the flash unit while transmitting a data packet. According to a particular embodiment of the invention, the means for transmitting and receiving data packets comprise means for activating a transmission signal before transmitting a data packet and means deactivating said transmission signal following transmission of said data packet, said transmission signal being received by the flash inhibiting means.

  According to a particular embodiment of the invention, the flash unit can be used in several modes involving different current consumption, the flash inhibition means operate only in some of said modes.

  The characteristics of the invention mentioned above, as well as others, will emerge more clearly on reading the following description of an exemplary embodiment, said description being given in relation to the attached drawings, among which: FIG. . 1 illustrates the radio resource in an OFDM system. Fig. 2 illustrates the current consumption of the communications management module in an exemplary embodiment of the invention. Fig. 3 illustrates the power consumption of the flash unit in an exemplary embodiment of the invention.

  Fig. 4 illustrates the implementation architecture of an exemplary embodiment of the invention. Fig. 5 illustrates the flow chart of an exemplary embodiment of the invention. In a wireless transmission system, for example in the GSM system (Global System for Mobile Communications in English), access to the radio resource is in a TDMA (Time Division Multiple Access) mode. In this mode, the communication is divided in the frequency space and in time. In the frequency space, the communication uses a set of carriers having specific frequencies according to an Orthogonal Frequency Division Multiplexing (OFDM) mode. The time space is divided into slices (Slot in English) of a fixed duration. This is illustrated in Fig. 1. This figure represents the radio resource, the frequency space is represented on the ordinate and the time on the abscissa. The elementary squares represent the slices corresponding to a given transmission time on a given frequency. Hatched slices represent the slices allocated to a given terminal. In a cellular network using this communication system, the different wireless communication terminals communicate with a base station. This broadcasts signals that the terminals will use to synchronize with the base station and therefore with the other terminals.

  They will then be assigned communication frequencies and time slots on these frequencies. The communication, and in particular the transmission of data by the terminal to the base station, intervenes discontinuously only during the time slots allocated to it. Those skilled in the art speak of the transmission of a TX, TX frame for transmission, to speak of the transmission of a data packet during a time slot allocated to the terminal for its radio communication. This phenomenon, which we will take advantage of, is found in any radio communication system using time slots for the transmission of data. From the point of view of the power consumption, this communication mode causes current calls at the battery during the transmission time of the TX frame. Indeed, during a radio communication, it is the emission that requires the most energy to generate the signal at the desired power so as to ensure transmission to the base station. Receiving a signal is significantly less energy intensive.

  This communication mode is used in a GSM system for both voice communication and data communications. In this system, the transmission of the TX frame typically lasts 1,154 ms. The transmission of such a TX frame occurs approximately every two seconds when the terminal is in standby mode. In a given communication, for example, the transmission frequency of a frame can go up to one frame every 4.6 ms or so. Fig. 2 describes the electrical intensity over time consumed by the terminal during a communication and in the absence of the operation of the photographic module. There are peaks 2.1 of electrical intensity corresponding to the emission of TX frames. Between these peaks, there is a consumption 2.2 corresponding to the power of the radio reception functions, the screen and management of the basic operation of the terminal. The exemplary embodiment of the invention is based on the use of a direct supply flash unit. The lamp used is an LED lamp. Unlike traditional xenon discharge lamps, these lamps do not require the rapid discharge of a large amount of current that must be accumulated in a component such as a capacitor. These LED flash units are powered directly by the terminal's current circuit and thus usually by the battery of the device. The luminous intensity depends directly on the electric intensity supplied. The duration of illumination depends, in turn, the time during which the flash unit is powered.

  As a result, the use of the flash causes a current draw on the current source, in this case the battery, concomitant with the duration of the illumination and proportional to the light intensity used. In the exemplary embodiment of the invention, the flash unit is used according to three modes of operation, a mode called torch mode, a preflash mode and a flash mode. These three modes of operation are adapted to the operation of the apparatus. The torch mode is a continuous mode of operation in which the intensity of illumination is relatively low. This intensity is calculated to be compatible with the operation of the transmitting radio unit. The amount of current required to transmit the TX frames by the radio unit with the amount of current required to use the flash unit in torch mode remains less than the amount of current that can be delivered by the source. current, that is to say the battery. Preflash mode is a mode in which the flash unit is used to produce a flash of light of limited duration. This mode is used before shooting by the camera unit of the terminal to perform the focus on the scene (Autofocus in English). The duration of the flash of preflash mode is typically of the order of 200 ms. This mode generally requires an illumination intensity higher than the intensity required during the torch mode.

  Flash mode is also a mode in which the flash unit is used to produce a flash of light of limited duration. This mode is used when shooting by the camera unit of the terminal. The duration of the flash light flash mode is typically of the order of 300 ms. This is the mode that generally requires the maximum light intensity.

  It is advantageous in terms of the accuracy of the focusing process and the quality of the image obtained when shooting to have a powerful flash unit. Indeed, the more powerful the flash unit is, the more it is possible to obtain good quality images under conditions of low natural illumination. Moreover, the more powerful the artificial illumination provided by the flash unit, the more it is possible to take distant subjects with low illumination and the faster the exposure time can be to avoid a blur effect on subjects moving. It is therefore advantageous to be able to power the flash unit with the maximum energy available at the energy source and therefore the battery.

  Flash units sized to produce, in both preflash and flash mode, an illumination corresponding to a current amount close to the maximum available current amount are therefore advantageous. The use of such powerful flash units involves a high power consumption during the duration of the flash of light in preflash mode and in flash mode. When using the flash in conjunction with a communication, the transmission of the TX frames during the flash flash results in the accumulation of the current draw due to the flash and that due to the emission of the frame TX. This current draw can exceed the capacity of the battery and lead to a collapse of the voltage delivered by it. It usually follows the failure of TX frame transmission and shooting. A first solution to this problem is to prohibit any communication during the operation of the photographic module. But if it is possible to prohibit voice communication during shooting, the user expects to be able to receive calls even when using the photographic function. In order to receive calls, the mobile terminal must report regularly to the base station. In addition, the user may want to use the photographic function of his terminal even while a data transmission is in progress. Due to the difference in typical duration between the emission of a TX frame on the one hand, about 1.15 ms, and the duration of use of the flash unit, from 200 to 300 ms, the inventors have It has been found that turning off the flash power for the duration of the transmission of the TX frames does not inconveniently reduce the illumination power of the flash unit. The images thus obtained have a quality quite correct. An embodiment of the invention therefore proposes a mechanism for switching off the power supply of the flash unit only during the transmission duration of the TX frames. This allows communications to be provided in conjunction with flash photography by the photographic unit. It is no longer necessary to make the communications and the use of the flash unit of the terminal exclusive.

  Fig. 4 illustrates the implementation architecture of an exemplary embodiment of the invention. The processor 4.1 manages the transmission of reception of radio signals. When this processor is preparing to transmit a TX frame, it activates the transmission signal 4.6. Signal 4.6 is inactivated at the end of transmission of the TX frame. This signal is received by the ISP 4.2 processor which manages, among other things, the flash unit 4.5 equipped with the LED flash 4.11. The processor activates the flash unit by activating the signal 4.7. This signal is processed by the logic unit Log 1 referenced 4.3 which takes as input the flash activation signal 4.7, the TX frame transmission signal 4.6 and the torch mode signal 4.8. The logical unit Log 1 emits the activation signal of the flash unit 4.10 controlling the operation of this flash unit 4.5. The signal 4.10 is active when the signal 4.7 is active and one of the signals 4.6 or 4.8 is inactive. A second logic unit 4.4 receives the input of the torch mode signal 4.8 and manages the signal regulating the power of the flash 4.12 connected to the input BRT of the flash unit. This input also receives signal 4.9 from preflash mode. The flash mode is therefore activated by the signal 4.7, the torch mode signals 4.8 and preflash mode 4.9 being inactive. In this mode, signal 4.10 is active and the flash unit turns on LED 4.11 at full power. If the signal 4.8 is active, the signal 4.9 being inactive, the lighting power is that of the torch mode, typically a quarter of the power of the flash mode. If, on the contrary, the preflash mode signal 4.9 is active and the torch mode signal is not, the illumination power is that of the preflash mode, typically half the power of the flash mode. The invention is implemented using the logic unit Log 1. This unit makes it possible to deactivate the activation signal of the flash unit 4.10 when the signal 4.6 is active, provided that the signal 4.8 does not not so. Indeed, it does not inhibit the operation of the flash when transmitting a TX frame when the flash is in torch mode. In this way, whether the flash is in flash mode or in preflash mode, the flash unit power is interrupted during the transmission periods of the TX frame signaled by the activation of the signal 4.6. On the other hand, when the flash is in torch mode, that is to say that the torch mode signal 4.8 is active, the activation of the transmission signal 4. 6 does not cause the inactivation of the signal activating the signal. flash unit 4.10. This mechanism therefore causes interruptions of short duration of the supply of the flash unit relative to the duration of a flash of flash. Recall that the typical transmission time of a TX frame is 1, 154 ms while the duration of the flash is 300 ms in flash mode and 200 ms in preflash mode. These times are indicative and may vary from one embodiment to another or from one use to another depending on the selected shooting parameters. Fig. 5 illustrates an embodiment of TX transmission management method taking into account the use of a flash unit.

  In a first step 5.1, there is initialization of the communication management and flash management modules. When the communication management module must send a TX frame, it starts by preparing it in a step 5.2. Then it activates the TX frame transmission signal in a step 5.3. It is tested in step 5.4 if the flash is active, or at least active in the flash or preflash mode in the embodiment described, the flash is disabled in step 5.5. This deactivation is to turn off the power of the flash. The TX frame is then sent during a step 5.6. Then, we test if the flash mode is still active during a step 5.7. If this is the case, the flash is reactivated in step 5.8. The method resumes in step 5.2 of preparing the TX frame during the next frame to be transmitted. It is obvious to those skilled in the art that the operation described herein is an example and that the embodiment of the invention may vary. The important thing is to turn off the power of the flash in the modes where it consumes a quantity of energy which, added to that of the emission of a TX frame, would be greater than the capacities of the energy source. In particular, the modes of use of the flash described here may vary from one embodiment to another as well as the illumination powers used.

Claims (1)

CLAIMS 1 / Method for managing a flash unit within a   radio communication terminal equipped with shooting capabilities, the communication being done by reception and transmission of data packets during allocated time slots, characterized in that it comprises a step of inhibiting the flash during transmission a packet of data. 2 / A method according to claim 1, the flash unit can be used in several modes involving different current consumption, characterized in that the flash inhibition step is performed in some of these modes. 3 / A method according to one of claims 1 or 2, characterized in that said inhibiting step comprises: - a step (5.3) of activation of a transmission signal prior to the transmission of the data packet; a step (5.5) for inactivating the flash if it is active; a step (5.6) of transmitting the data packet; a step (5.8) of reactivating the flash when the data packet is sent. 4 / radio communication terminal comprising: means for transmitting and receiving data packets during allocated time slots; - shooting means; - a flash unit; characterized in that it further comprises: - means for inhibiting the flash unit during transmission of a data packet. 5 / communication terminal according to claim 4, characterized in that the means for transmitting and receiving data packets comprise means for activating a transmission signal prior to issuing a data packet and means for deactivating said transmission signal following the transmission of said data packet, said transmission signal being received by the flash inhibition means. 6 / communication terminal according to claim 5, the flash unit can be used in several modes involving different current consumptions, characterized in that the flash inhibition means operate only in some of said modes.