DE10051530A1 - Circuit layout for use with a fixed hard disk drive assembly has a hard disk drive assembly, a mains supply circuit, a digital part and a mains-fed circuit component with delay action through a switch in relation to switching on. - Google Patents

Abstract

A circuit layout has a fixed hard disk drive assembly (HDD), a mains supply circuit (PS), a digital part (DP) and a mains-fed circuit component (LNB) with delay action through a switch mechanism (SW) in relation to switching on. As the HDD reaches a normal operating condition or peak current suffers a serious drop during run-up phase, the circuit component is turned on.

Description

The invention relates to a circuit arrangement with a Hard drive as data storage, a power supply for Power supply to the circuit arrangement and one Digital part for processing data. switching Arrangements of this type are, for example, by Computer systems such as home computers (PC) and notebooks known. Due to the enormously increased capacity of Hard drives are cheap at the same time however, other applications are foreseeable, such as in Set-top boxes, digital satellite receivers or digital ones TV sets for storing video and audio data.

Use hard drives to store the digital Data a stack of plates, the surface of which with a magnetizable layer is coated, and that for reading and writing over the data from magnetic heads become. The hard disk stack rotates during operation at a constant speed that is as high as possible to be both a high data rate and a enable fast access time. current Rotation speeds are around 5000 to 10000 Revolutions per minute. When turning on the Hard disk drive therefore needs a motor certain ramp-up times with significantly higher power requirements, until the hard drive reaches its operating state Has. The power supply of the circuit arrangement must therefore Switch on a correspondingly higher performance provide, but only for the startup of the Hard drive is needed. The power supply is therefore for the Normal operation of the circuit arrangement oversized, what a poorer efficiency with a higher Energy consumption and a higher switching effort Consequence.

A circuit arrangement of this type is, for example, from WO 95/10110 known, which relates in particular to  Computer systems related to a hard drive. she also relates to the problem of the high Peak current while booting the hard drive until the speed is stabilized, and therefore a power supply with higher performance is needed. Here it is suggested in Hard drive a microcontroller with different Use control programs for startup, and the either selected with hardware or software can be. This can be particularly useful for portable Laptop or notebook computer using a first one Control program with a longer ramp-up time accordingly lower peak current can be chosen while for others Computer systems through a second control program enables the hard drive to ramp up quickly.

The object of the present invention is a Specify circuit arrangement of the type mentioned at the outset, which has an inexpensive and efficient power supply.

This object is achieved by those specified in claim 1 Features solved. Advantageous developments of the invention are specified in the subclaims. Furthermore, in Claim 9 a method for turning on Circuit components of the circuit arrangement specified, the the switch-on behavior of the circuit arrangement according to the Claims 1 to 8 corresponds.

The circuit arrangement according to the invention has Hard drive, a power supply, a digital part as well at least one further circuit component, wherein this circuit component is delayed by switching means regarding a moment of turning on the power supply with Electricity is supplied. Only when the hard drive for example, has reached a normal operating state or the peak current considerably during the startup phase has dropped, the circuit component switched on. This will cause the power supply to turn on less stressed and can be for a lower maximum  Output power can be designed. Turning on the different circuit components is here by the Digital part, in particular a microcontroller has controlled. The other circuit component is for example a component for the operation of which Hard drive must already be started, or the is only needed in less frequent cases.

The circuit arrangement is, for example, in one digital satellite receiver that is an external Circuit component such as a low-noise Converter powered, a set-top box, or in a TV with a hard drive realized. These devices usually have one Standby or standby on with a very low power and normal operation in which all Circuit components are powered. At the Can switch from standby to normal operation due to the delayed switch-on, the load on the Power supply can be significantly reduced. The digital part points especially a microcontroller that is in standby Operation is switched on, and the switching on of the Controls circuit components.

The power supply therefore does not have to be oversized to to absorb the higher peak load in the switch-on phase. An oversized power supply is also special critical in the event of a short circuit, which may then occur is more difficult to determine or a higher one Circuitry required in the power supply to be high To enable security of the device.

The invention is exemplified below with reference to Drawings explained in more detail. Show it:

Fig. 1 shows a circuit arrangement with a drive disks,

FIG. 2 shows a performance diagram with a switch-on phase of the circuit arrangement according to FIG. 1, and

Fig. 3 shows another embodiment of a switch-on phase of the circuit of FIG. 1.

The circuit arrangement shown in FIG. 1 has a power supply PS, a hard disk drive HDD, a digital part DP and further circuit components, a so-called low-noise converter LNB and an analog part AP. In this exemplary embodiment, it represents a digital satellite receiver SR with a connected low-noise converter LNB, the low-noise converter LNB being arranged separately and as close as possible to a satellite antenna A. In this exemplary embodiment, the LNB is supplied with current by the power supply PS of the satellite receiver SR.

The power supply PS is used to supply power to the individual circuit components and is usually a switched-mode power supply that is fed by an AC network, in this exemplary embodiment 220 volts. On the output side, it has corresponding connecting lines 1 , 2 and 3 to the hard disk drive HDD, the digital part DP, and the further circuit components LNB and analog part AP.

The power supply for the low-noise converter LNB is usually conducted via a coaxial cable 4 , with which the low-noise converter LNB is connected to the satellite receiver SR, since the high-frequency AC component of the low-noise converter output and the DC component of the power supply PS can be separated in a simple manner. The low-noise converter LNB is a low-noise input stage for the weak output signal of satellite antenna A, which is in the frequency range of 10-12 GHZ, for example, and is mixed down to a lower intermediate frequency by a first mixer stage in the LNB. As a result, the intermediate frequency signal can also be led to the satellite receiver SR with a low loss via a longer coaxial cable 4 , since the low-noise converter LNB must be arranged directly on the satellite antenna A.

The intermediate frequency signal of the low-noise converter LNB is fed via the coaxial cable 4 to an analog part AP of the satellite receiver SR, in which it is mixed down into a baseband by a further mixer, in which the data is then transmitted from the digital part DP, which is via an interface 6 is connected to the analog part AP to be processed further. The digital part DP is also connected via an interface 5 to the internal hard disk drive HDD, on which television programs controlled by a user can be stored, and via a further interface 7 , for example a Scart connection, with other devices such as a TV or TV set connected to a VCR.

The digital part DP of the satellite receiver SR has, in particular, a microcontroller μC which controls the operation of the satellite receiver SR and responds to commands from a user via a user interface. This user interface, which usually comprises an infrared receiver in the satellite receiver SR and a remote control, is not shown in FIG. 1 for reasons of clarity.

The digital satellite receiver SR has one Standby mode, also called standby mode, in which the satellite receiver has low energy consumption has, as in consumer electronics devices common. In this are essential circuit components of the SR satellite receiver is switched off, it makes it possible but a user using the remote control to put the device in toggle normal operation by all  Circuit components are turned on for execution all device functions of the SR satellite receiver. While The HDD hard disk drive is intended for normal operation be in constant use as this will result in the user is made possible by a corresponding control command to start recording immediately. A change between Standby operation and normal operation is performed by one User controlled, for example, by the microcontroller µC executed and is known according to the prior art.

According to the invention, the power supply PS has a switching means SW, which is controlled in this exemplary embodiment by the microcontroller μC and by means of which the low-noise converter LNB is switched on with a delay via connection 2 when switching from standby mode to normal mode. The hard disk drive HDD is switched on immediately and draws a high current until the hard disk has started up. At the same time, both the digital part DP and the analog part AP are supplied with current. Since the low-noise converter LNB is only switched on later, the load on the power supply PS when switching from standby to normal operation is thereby considerably reduced, as explained in more detail below with reference to FIG. 2.

The switching means SW is, for example, a transistor switch or a voltage regulator, which is switched on and off by the microcontroller μC via the connection 2 . The delayed switching on of a circuit component can of course also be carried out if the circuit arrangement has only normal operation, no standby operation, or goes directly into normal operation when switched on. Further circuit components that can be switched on with a delay are, for example, semiconductor memory components, such as RAM and ROM memory. These semiconductor memories can be switched to a power-down mode by a so-called CE signal.

For example, with a digital television, the is provided with a hard disk drive when Switching on normal operation the memory components for an image memory or the teletext memory is delayed be switched on. With a computer system you can corresponding circuit components also delayed be switched on, for example with a laptop Computer that has the CD-ROM or DVD drive switched on after switching on the device with a delay.

In Fig. 2, the switch-on behavior of the circuit arrangement according to FIG. 1 is shown in a power diagram in watts as a function of time t. From a point in time t0, the circuit arrangement is in a standby mode STB with, for example, 4 watts, in which essentially only the power supply PS and components for the remote control in the satellite receiver SR are in operation, as already explained with reference to FIG. 1. At a time t2, the satellite receiver SR is switched on by a user, so that the user switches to normal operation. As a result, the power requirement of the circuit arrangement increases considerably, since the digital part DP consumes approximately 20 watts and the hard disk drive HDD 6 watts in normal operation and as an additional load during the boot phase of the hard disk requires an additional 20 watts. This results in a peak load of approx. 50 watts for the PS power supply unit, with the low-noise converter LNB still switched off in this phase.

After a period of about 5 to 10 seconds, to one Time t2 is dependent on the hard disk drive HDD the hard disk started up, so that the Power requirement reduced to 30 watts. At a time t3 the low-noise converter LNB is then switched on, which increases the power consumption to 40 watts, and remains approximately at this value during normal operation. However, the time t3 can also occur before the time  t2 can be selected if, for example, a short Switch-on phase for the circuit arrangement is desired, or if the hard drive starts up during the boot phase Power requirements of the hard disk drive are already considerable has sunk.

The time at which the low-noise converter LNB is switched on can be specified, for example, by a control signal from the hard disk drive HDD, with which the drive indicates that the hard disk has started up or is in operation. Another option is to switch on the low-noise converter LNB for a predetermined time, for example five seconds after switching on normal operation. The power supply PS according to FIG. 1 therefore only needs to be dimensioned for a power requirement of 50 watts plus approximately 20% reserve, that is to say a total of 60 watts, whereas it would have to be designed for approximately 70 to 75 watts when all circuit components are switched on at the same time. The power supply unit, for example a switching power supply unit, can thereby be constructed more cost-effectively and the conditions in the event of a short circuit are less critical.

A further exemplary embodiment of a method for starting up the circuit arrangement according to FIG. 1 is explained below on the basis of a performance diagram as indicated in FIG. 3. Here, too, the switched-mode power supply of the circuit arrangement is switched from a standby mode STB to normal mode ON at a time t1, in that essentially only the hard disk HDD is switched on at time t1. As soon as the peak power of the hard disk drive HDD has been reduced to the normal power, at a time t2, further components such as the digital part DP are subsequently connected at a time t3. This switch-on time can be determined, for example, via a current sensor of the hard disk drive or via a fixed time. At a further point in time t4, the low-noise converter LNB is finally switched on.

Claims (11)

1. Circuit arrangement with a hard disk drive (HDD), a power supply (PS), a digital part (DP), and with at least one further circuit component (LNB), characterized in that the circuit arrangement has a switching means (SW) through which the further circuit component (LNB) is switched on with a delay when the circuit arrangement is switched on. 2. Circuit arrangement according to claim 1, characterized characterized that component (LNB) from the power supply (PS) is powered if that Hard disk drive (HDD) its normal operating state has reached or the peak current during the Ramp-up phase has dropped significantly. 3. Circuit arrangement according to claim 1 or 2, characterized characterized in that the component (LNB) around a fixed predetermined time is switched on with a delay, or after a control signal from the hard disk drive (HDD) is switched on. 4. Circuit arrangement according to claim 1, 2 or 3, characterized characterized in that the digital part (DP) Microcontroller (µC), which turns on the Controls circuit components. 5. Circuit arrangement according to one of the preceding Claims, characterized in that the Circuit arrangement a normal operation and one Standby mode in which the microcontroller (pe) is turned on, and that Hard disk drive (HDD) when the Normal operation is switched on.   6. Circuit arrangement according to one of the preceding Claims, characterized in that the power supply (PS) on the output side a switch (SW) or a Has voltage regulator over which the further Circuit component (LNB) from the microcontroller (µC) is switched on in a controlled manner. 7. Circuit arrangement according to one of the preceding Claims, characterized in that further Circuit components of the circuit arrangement, such as RAM and / or ROM storage devices during the Are switched on and after a predefined time interval switched on with a delay become. 8. Circuit arrangement according to one of the preceding Claims, characterized in that the Circuitry in a digital satellite Receiver (SR) in connection with a low-noise Converter (LNB), a set-top box or in one digital TV is used. 9. Procedure for starting up a circuit arrangement, which is a power supply (PS), a hard disk drive (HDD), a digital part (DP) and at least one more Has circuit component (LNB), thereby characterized in that the further component (LNB) at Switch on the circuit arrangement only from the power supply (PS) is powered when that Hard disk drive (HDD) its normal operating state has reached or the peak current in the Ramp-up phase has dropped significantly. 10. The method according to claim 9, characterized in that further circuit components of the circuit arrangement, such as RAM and / or ROM storage units, during the Are switched on and after a  defined time interval switched on with a delay become. 11. The method according to claim 9 or 10, characterized characterized in that the component (LNB) around a fixed predetermined time is switched on with a delay, or after a control signal from the hard disk drive (HDD) is switched on.