JP7328010B2 - A power receiving device and its control circuit, a method of negotiation between the power feeding device and the power receiving device - Google Patents

Description

The present invention relates to technology for supplying power to electronic equipment.

Battery-driven devices such as mobile phone terminals, smart phones, tablet terminals, notebook computers, and portable audio players incorporate a rechargeable secondary battery and a charging circuit for charging the battery. Some charging circuits charge a secondary battery based on a DC voltage (bus voltage V _BUS ) externally supplied via a USB cable or a DC voltage from an external AC adapter.

At present, charging circuits installed in mobile devices are mainly compatible with a standard called USB Battery Charging Specification (hereinafter referred to as BC standard). There are several types of USB hosts or chargers (hereinafter collectively referred to as USB power supply devices). In the BC revision 1.2 standard, SDP (Standard Downstream Port), DCP (Dedicated Charging Port), and CDP (Charging Downstream Port) are defined as types of USB power supply devices. The current (current capacity) that can be supplied by the USB power supply device is defined according to its type. Specifically, DCP and CDP specify 1500 mA, and SDP specifies 100 mA, 500 mA, and 900 mA according to the USB version.

A standard called USB Power Delivery (hereinafter referred to as PD standard) has been formulated as a next-generation secondary battery charging method and system using USB. In the PD standard, the power that can be supplied is greatly increased from 7.5 W in the BC standard to a maximum of 100 W. Specifically, the PD standard allows the supply of a voltage higher than 5 V (specifically, 9 V, 12 V, 15 V, 20 V, etc.) as the USB bus voltage, and the charging current is also larger than the BC standard. (Specifically, 2A, 3A, 5A, etc.) supply is allowed. The PD standard is also adopted by the USB type-C standard.

FIG. 1 is a block diagram of a power supply system 100R studied by the inventors. This power supply system 100R conforms to the USB Type-C standard, and includes a power supply device 200R and a power receiving device 300R that are connected via a USB cable 106. FIG. For example, the power supply device 200R is mounted on the AC adapter 102 or mounted on an electronic device. The power receiving device 300R is installed in a battery-driven electronic device 400 such as a smart phone, tablet terminal, digital camera, digital video camera, or portable audio player.

The power supply device 200</b>R includes a power supply circuit 202 and a power supply side PD controller (hereinafter referred to as a power supply side controller) 204 . A list or table of SOURCE PDOs (Power Data Objects) (hereinafter also simply referred to as a PDO list) 206 can define up to seven combinations of voltage and current (PDOs) that can be supplied by the power supply device 200R.

A USB cable 106 is detachably connected to a receptacle 404 of the electronic device 400 . There is also a charging adapter in which the receptacle 404 is omitted and the USB cable 106 is integrated with the AC adapter 102 .

Receptacle 404 includes a VBUS terminal for supplying bus voltage _VBUS , a GND terminal for supplying ground voltage _VGND , and a CC (Configuration Channel) terminal. Although two CC terminals are provided in the receptacle type, only one CC terminal is shown in this specification. A power supply circuit 202 generates a bus voltage V _BUS . Power supply circuit 202 may include an AC/DC converter that receives AC 100V from an external power supply (eg, commercial AC power supply) (not shown) and converts it into a DC bus voltage V _BUS . A bus voltage V _BUS generated by the power supply circuit 202 is supplied to the power receiving device 300R via the bus line of the USB cable 106 .

The power-supply-side controller 204 is connected to a power-receiving-side PD controller (hereinafter referred to as a power-receiving-side controller) 310 via a USB cable 106 . The power supply controller 204 and the power reception controller 310 provide a communication function between the power supply device 200R and the power reception device 300R.

The electronic device 400 includes a load (system) 402 in addition to the power receiving device 300R. The load 402 includes a CPU, memory, liquid crystal display, audio circuit, and the like. AC adapter 102 is detachably connected to receptacle 404 via USB cable 106 .

The power receiving device 300 R includes a battery 302 , a charging circuit 304 , a power supply circuit 306 , a DC/DC converter 308 , a power receiving side controller 310 , and a list or table of SINK PDOs (hereinafter also simply referred to as a PDO list) 312 .

Battery 302 is a rechargeable secondary battery. The charging circuit 304 receives a bus voltage V _BUS (also referred to as an adapter voltage V _ADP on the power receiving device 300R side) from the power feeding device 200R via the USB cable 106 and charges the battery 302 . The charging circuit 304 is composed of a step-down DC/DC converter, a linear regulator, or a combination thereof.

System voltage V _SYS corresponding to at least one of adapter voltage V _ADP and voltage V _BAT of battery 302 is supplied from charging circuit 304 to load 402 . The load 402 includes a power management IC (Integrated Circuit), a multi-channel power supply including a DC/DC converter, a linear regulator, etc., a microcomputer, a liquid crystal display, a display driver, and the like.

The load 402 operates, for example, at a system voltage V _SYS =20 V and a maximum current of 2.25 A (power of 45 W). On the other hand, the electronic device 400 supports a bus voltage V _BUS of 15V in addition to a bus voltage V _BUS of 20V. In PDO list 312, the voltage and current required by electronic device 400 are declared as PDOs. In this example, (20V, 2.25A) and (15V, 3A) are declared as PDOs. In addition, the USB PD standard requires that both the power supply side and the power receiving side support 5V (current is not specified).

For this purpose, a power supply circuit 306 is provided in the preceding stage of the charging circuit 304 . Power supply circuit 306 includes a DC/DC converter 308 . DC/DC converter 308 boosts V _BUS =15V (or 5V) to produce an adapter voltage V _ADP of 20V.

The power receiving side controller 310 is a port controller related to USB Type-C, and is connected to the power feeding side controller 204 via the CC line. When the AC adapter 102 and the electronic device 400 are connected, the power supply side controller 204 and the power receiving side controller 310 negotiate to determine the voltage level of the bus voltage V _BUS based on the PDO list 206 and the PDO list 312. .

FIG. 2 is a sequence diagram of negotiation in the USB PD standard of FIG. First, the power-supply controller 204 transmits the PDO list 206 to the power-receiving controller 310, and declares voltage and current that can be supplied (referred to as Source Capability) (S100).

The power receiving controller 310 refers to the PDO list 312 and selects one optimum PDO from the PDO list 206 (S102). Then, the power receiving controller 310 transmits an RDO (Request Data Object) including the selected PDO and the amount of current to be used (S104). If the amount of current that the power supply device 200R can supply falls short of the amount of current that the power receiving device 300R requests, the RDO includes information indicating a mismatch. As a result, the power receiving device 300R notifies the power feeding device 200R of the negotiation with the unintended PDO.

The power supply controller 204 that has received the RDO sets the output voltage V _BUS of the power supply circuit 202 to the value indicated by the RDO (S106). Note that the current _IRQ requested by the PDO list 312 and the current declared in the PDO list 206 do not necessarily match.

For example, suppose power supply device 200R supports four PDO1-PDO4 declared in PDO list 206 of FIG. Focusing on the power receiving device 300R side, since voltage conversion by the DC/DC converter 308 causes power loss, the bus voltage V _BUS of 20 V can operate more efficiently. Therefore, power receiving controller 310 selects PDO4 (20 V, 2.25 A) from the PDO list received in step S100, and transmits RDO including PDO4 and 2.25 A of current consumed by electronic device 400. FIG. In this case, the feeding system 100R is working fine.

JP 2013-198262 A JP-A-2006-60977 Japanese Patent Application Laid-Open No. 2006-304500

As a result of examining the power supply system 100R of FIG. 1, the inventors have come to recognize the following problems.

The power rule of the USB PD standard stipulates that the PDO with the highest voltage value in the PDO list 206 of the power supply device 200R should have the highest power. In combination with the adapter 102 conforming to this power regulation, the power receiving device 300R can automatically receive power at the maximum power (45 W) by selecting the PDO with the maximum voltage (PDO4 in this example). can.

However, some adapters 102 have PDO lists 206 that do not comply with power regulations. For example, it is assumed that the power supply device 200R has the following PDO list.
PDO1: 5V, 3A
PDO2: 9V, 3A
PDO3: 15V, 3A
PDO4: 20V, 0.5A

In this case, if the power receiving device 300R selects PDO4 with the highest voltage value, it can receive only 10 W (20 V×0.5 A) of power from the power feeding device 200R that has a power supply capability of 45 W (15 V×3 A). A situation arises. That is, since the supplied power of 10 W falls below the required power of 45 W, the electronic device 400 cannot be properly operated.

The negotiation method of the power receiving device 300R is left to the designer. As another example, a method of prescribing a requested voltage range (maximum voltage and minimum voltage) and a requested current _IRQ instead of the PDO list 312 in the power receiving device 300R is also conceivable. In this case, the power receiving device 300R selects the PDO with the maximum voltage value within the requested voltage range from the PDO list received from the power feeding device 200R, adds the requested current _IRQ , and generates the RDO.

Consider the case where the requested current _IRQ is the minimum current that the power receiving device 300R can sink. For example, assume that the power receiving device 300R has a required voltage range of 15 to 20V and a required current I _RQ =2.25A. Also, the PDO list on the side of the power supply device 200R is
(Example 1)
PDO1=5V, 3A
PDO2=9V, 3A
PDO3=15V, 3A
PDO4=20V, 2.25A
Suppose that In this case, the power receiving device 300R selects PDO4, which has the highest voltage within the required voltage range, from among PDO1 to PDO4. At this time, negotiation is established at 20V and 2.25A.

(Example 2)
If the PDO list on the side of the power supply device 200R is
PDO1=5V, 3A
PDO2=9V, 3A
PDO3=15V, 3A
, the PDO3 having the maximum voltage within the required voltage range is selected, negotiation is performed at 15V and 2.25A, and the supplied power of 33.75 is less than the required power of 45W.

In order to solve this problem, it is conceivable to determine the required current _IRQ from the required power and the minimum value of the required voltage range instead of the minimum current. In this example, the required power is 45 W and the minimum value of the required voltage range is 15 V, so the required current _IRQ is 45 W, 15 V=3 A. In this case, PDO3 (15V) is selected for the PDO list of Example 2, and negotiation is established with a combination of 15V and 3A, which is the requested current _IRQ .

However, for the PDO list of Example 1, PDO4 (20V) is selected, and negotiation is performed with a combination of 20V and 3A, which is the requested current _IRQ . Since the power supply device 200R does not have a supply capability of (20V, 3A), the negotiation fails.

Note that such a problem can occur not only in USB PDs but also in power feeding systems having protocols similar to USB PDs.

The present invention has been made in view of such problems, and one exemplary object of certain aspects thereof is to provide a power receiving device capable of receiving appropriate power supply from power feeding devices having various PDO lists, or The purpose is to provide a control circuit.

One aspect of the present invention relates to a control circuit for a power receiving device that receives power from a power feeding device. The control circuit receives from the memory holding the minimum required power P _MIN and from the power supply device a list of first data defining the combinations of voltage V and current I that the power supply device can supply, and the first data contained in the list For each data, calculate the power P which is the product of the voltage V and the current I contained in it, select the first data whose power P is greater than the minimum required power _PMIN , and select the second data based on the selected first data. a controller that transmits to the power supply device.

It should be noted that arbitrary combinations of the above-described constituent elements and mutually replacing the constituent elements and expressions of the present invention in methods, devices, systems, etc. are also effective as embodiments of the present invention.

According to the power receiving device according to an aspect of the present invention, it is possible to receive power with an appropriate combination of voltage and current in combination with various power feeding devices.

1 is a block diagram of a power supply system examined by the inventors; FIG. FIG. 2 is a sequence diagram of negotiation in the USB PD standard of FIG. 1; 1 is a block diagram of a power supply system according to Embodiment 1; FIG. 4A and 4B are diagrams for explaining the operation of the power supply system. FIG. 11 is a diagram for explaining the operation of the power supply system according to Modification 1; 6A and 6B are diagrams for explaining the operation of the power supply system according to Modification 2. FIG. FIG. 12 is a diagram for explaining the operation of the power supply system according to Modification 3; FIG. 12 is a diagram for explaining the operation of the power supply system according to Modification 4;

(Overview of Embodiment)
One embodiment disclosed herein relates to a control circuit used in a power receiving device that receives power from a power supply device. The control circuit receives from the memory holding the minimum required power P _MIN and from the power supply device a list of first data defining the combinations of voltage V and current I that the power supply device can supply, and the first data contained in the list For each data, calculate the power P which is the product of the voltage V and the current I contained in it, select the first data whose power P is greater than the minimum required power _PMIN , and select the second data based on the selected first data. a controller that transmits to the power supply device.

According to this embodiment, it is possible to prevent power supply due to a combination of voltage and current below the minimum required power P _MIN .

The controller may select the first data with the maximum power P when there are a plurality of first data in which the power P, which is the product of the voltage V and the current I, exceeds the minimum required power P _MIN . This is effective when the power receiving device includes a battery charger, and can shorten the charging time.

The controller may select the first data with the highest voltage V when there are a plurality of first data in which the power P, which is the product of the voltage V and the current I, exceeds the minimum required power P _MIN . This can reduce power loss.

The controller selects the first data with the maximum power P when there are a plurality of first data in which the power P, which is the product of the voltage V and the current I, exceeds the minimum required power P _MIN . A voltage priority mode that selects the first data with the largest V may be selectable. Accordingly, two modes can be selected according to the operating state of the electronic device in which the power receiving device is mounted.

The memory may further retain the maximum required power P _MAX . When the power P, which is the product of the voltage V and the current I of the first data, exceeds the maximum required power P _MAX , the controller modifies the current to I′=P _MAX /V, and selects the modified first data , the corrected current is the requested current _IRQ . As a result, it is possible to supply power with the maximum required power P _MAX by making the most of the capability of the power supply device.

The memory may also hold the maximum current I _MAX . The controller may modify the current I of the first data to the maximum current I _MAX when there is a first data in which the current I exceeds the maximum current I _MAX . As a result, the power supply device can maximize its supply capability as long as the maximum current is not exceeded.

When the voltage V range is defined in the first data, the controller may set the power P to the product of the minimum value of the voltage V range and the current I.

The memory may also retain the voltage range required by the powered device. The controller may exclude first data for which the voltage V is outside the voltage range.

The control circuit may be monolithically integrated on one semiconductor substrate. "Integrated integration" includes cases in which all circuit components are formed on a semiconductor substrate and cases in which the main components of a circuit are integrated. A resistor, capacitor, or the like may be provided outside the semiconductor substrate. By integrating the circuits on one chip, the circuit area can be reduced and the characteristics of the circuit elements can be kept uniform.

The control circuit may comply with the USB PD standard. "Compliant" includes a case where the compliance test is passed (Compliant), or a case where the compliance test is not passed but the operation is supported (Compatible).

(Embodiment)
BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below based on preferred embodiments with reference to the drawings. The same or equivalent constituent elements, members, and processes shown in each drawing are denoted by the same reference numerals, and duplication of description will be omitted as appropriate. Moreover, the embodiments are illustrative rather than limiting the invention, and not all features and combinations thereof described in the embodiments are necessarily essential to the invention.

In this specification, "a state in which member A is connected to member B" refers to a case in which member A and member B are physically directly connected, or a case in which member A and member B are electrically connected to each other. It also includes the case of being indirectly connected via other members that do not substantially affect the connected state or impair the functions and effects achieved by their combination.

Similarly, "the state in which member C is provided between member A and member B" refers to the case where member A and member C or member B and member C are directly connected, as well as the case where they are electrically connected. It also includes the case of being indirectly connected through other members that do not substantially affect the physical connection state or impair the functions and effects achieved by their combination.

FIG. 3 is a block diagram of power supply system 100 according to the embodiment. The power supply system 100 is compliant with the USB Type-C standard as in FIG. For example, power supply device 200 is mounted on AC adapter 102 or mounted on an electronic device. The power receiving device 300 is installed in a battery-driven electronic device 400 such as a smart phone, tablet terminal, notebook PC, digital camera, digital video camera, or portable audio player.

The basic functions of each of power supply device 200 and power reception device 300 are as described with reference to FIG.

The power supply device 200 comprises a power supply circuit 202 and a control circuit 201 capable of generating a variable bus voltage V _BUS . The control circuit 201 includes a power supply side PD controller (hereinafter referred to as a power supply side controller) 204 and a memory 207 that stores a PDO (first data) list 206 . The control circuit 201 may be a functional IC integrated on one semiconductor substrate. The power supply circuit 202, power supply controller 204, and PDO list 206 are as described with reference to FIG.

PDO list 206 includes at least one data (PDO) defining the voltage V and current I that can be supplied by power supply circuit 202 . The i-th (i=1, 2, . . . ) PDO is denoted by PDOi, its voltage value is denoted by V _i , and its current value is denoted by I _i . The power supply controller 204 can communicate with the power receiver controller 310 of the power receiver 300, negotiates the supply voltage using the PDO list 206, and causes the power supply circuit 202 to generate the determined supply voltage.

Next, the configuration of the power receiving device 300 will be described. The power receiving device 300 includes a control circuit 301 , a battery 302 , a charging circuit 304 and a power supply circuit 306 .

Battery 302 is a rechargeable secondary battery. Charging circuit 304 receives bus voltage V _BUS (also referred to as adapter voltage V _ADP on the power receiving device 300 side) from power supply device 200 via USB cable 106 and charges battery 302 . Charging circuit 304 is composed of a DC/DC converter, a linear regulator, or a combination thereof.

System voltage V _SYS corresponding to at least one of adapter voltage V _ADP and voltage V _BAT of battery 302 is supplied from charging circuit 304 to load 402 . The load 402 includes a power management IC (Integrated Circuit), a multi-channel power supply including a DC/DC converter, a linear regulator, etc., a microcomputer, a liquid crystal display, a display driver, and the like.

The control circuit 301 is a functional IC that includes a power receiving controller 310 and a memory 320 and is integrated on one semiconductor substrate. Note that the controller of the DC/DC converter 308 and the charging circuit 304 may be integrated in the control circuit 301 in addition to the power receiving controller 310 and the memory 320 .

Memory 320 holds minimum required power P _MIN of power receiving device 300 .

Power receiving controller 310 receives from power supply device 200 a list of PDOs (first data) that define combinations of voltage V and current I that power supply device 200 can supply. Then, for each PDOi (i=1, 2 . . . , n) contained in the list 206, the power P _i that is the product of the voltage V _i and the current I _i contained therein is calculated. Then, one of the plurality of PDO1 to PDOn is selected, the power P of which is greater than the minimum required power P _MIN .

Then, second data based on the selected PDO data (hereinafter referred to as RDO: Request Data Object) is transmitted to the power supply device 200 . The power supply device 200 sets the voltage V _BUS generated by the power supply circuit 202 based on the RDO received from the power reception device 300 .

The above is the configuration of the power supply system 100 . Next, the operation will be explained.

4A and 4B are diagrams for explaining the operation of the power supply system 100. FIG. For example, assume that the minimum required power P _MIN specified in memory 320 is 27W. In the example of FIG. 4A, the PDO list 206 includes two PDO1 and PDO2.
PDO1: _V1 =5V, _I1 =3A
PDO2: _V2 =9V, _I2 =3A

The power receiving controller 310 calculates powers P ₁ and P ₂ of the two PDO1 and PDO2, respectively.
_P1 = _V1 * _I1 =15W
_P2 = _V2 * _I2 =27W

Of the two powers P ₁ and P ₂ , only P ₂ is greater than the minimum required power P _MIN . Therefore, the power receiving controller 310 determines the RDO based on the second PDO2. RDO in this case contains information on voltages V=9V and I=3A.

In the example of FIG. 4B, the PDO list 206 includes four PDO1-PDO4.
PDO1: _V1 =5V, _I1 =3A
PDO2: _V2 =9V, _I2 =3A
PDO3: _V3 =15V, _I3 =3A
PDO4: _V4 = 20V, _I4 = 1.35A

The power receiver controller 310 calculates powers P ₁ -P ₄ for the four PDO1-PDO4, respectively.
_P1 = _V1 * _I1 =15W
_P2 = _V2 * _I2 =27W
_P3 = _V3 * _I3 =45W
_P4 = _V4 * _I4 =27W

Of the four powers P ₁ to P ₄ , powers P ₂ to P ₄ are greater than the minimum required power P _MIN . In this case, the power receiving controller 310 selects one of the three PDO2 to PDO4 to determine the RDO. A method of selecting one PDO from a plurality of PDO candidates will be described below.

(First method)
For example, when there are multiple PDOs with power P exceeding the minimum required power _PMIN , the power receiving controller 310 may select the PDO with the largest power P. In this example, since P ₃ =45 W is the maximum, PDO3 is selected and RDO is determined based on PDO3. In a device containing the battery 302, when charging the battery 302, the charging time can be shortened as the supplied power is larger.

If there are a plurality of PDOs with the maximum power P, the one with the maximum voltage V may be selected from among them.

(Second method)
The receiving-side controller 310 may select the PDO with the highest voltage V when there are multiple PDOs whose power P exceeds the minimum required power _PMIN . In this example, since V ₄ =20V is the maximum, PDO4 is selected and RDO is determined based on PDO4.

When the DC resistance of the power supply path from the power supply circuit 202 to the charging circuit 304 is R, the loss in this power supply path is R× ^I2 . When the same power is supplied, the higher the voltage V, the smaller the current I, so power loss can be reduced.

If there are a plurality of PDOs with the maximum voltage V, the one with the maximum power P may be selected from among them.

(Third method)
The power receiving controller 310 may be capable of dynamically switching between the power priority mode and the voltage priority mode according to the state of the electronic device 400 . That is, the voltage priority mode may be selected when the battery 302 is fully charged, and the power priority mode may be selected when the remaining amount of the battery 302 is low.

Alternatively, the power receiving controller 310 may maintain voltage priority. For example, the conversion efficiency of DC/DC converter 308 may have an input voltage (ie, V _BUS ) dependency. In this case, the order of the voltages with the highest conversion efficiency may be stored in the memory 320, and the PDO including the voltage giving the highest conversion efficiency may be selected.

The basic configuration and operation of the power supply system 100 have been described above. According to this power feeding system 100, the power supplied from the power feeding device 200 to the power receiving device 300 can be optimized. Specifically, the power supplied from the power supply device 200 to the power receiving device 300 can be prevented from falling below the required power of the power receiving device 300 .

Further, by determining whether priority is given to voltage or power, electronic device 400 can be operated in an optimal state.

Next, a modification of the power receiving device 300 will be described.

(Modification 1)
Consider a case where the power that the power receiving apparatus 300 can receive has an upper limit. The memory 320 holds an upper limit of power (hereinafter referred to as maximum required power P _MAX ) in addition to the minimum required power P _MIN .

When the power P _j =V _j ×I _j , which is the product of the voltage V _j and the current I _j of the PDO j, exceeds the maximum required power P _MAX , the power receiving controller 310 reduces the current of the PDO i to I _i ′=P _MIN /V _i . Then, when the modified PDOi is selected, the requested current I _RQ included in the RDO is set to I _i '.

FIG. 5 is a diagram for explaining the operation of the power supply system 100 according to Modification 1. As shown in FIG. The minimum required power P _MIN defined in the memory 320 is 27W and the maximum required power P _MAX is 45W. PDO list 206 includes four PDO1-PDO4.
PDO1: _V1 =5V, _I1 =3A
PDO2: _V2 =9V, _I2 =3A
PDO3: _V3 =12V, _I3 =3A
PDO4: _V4 = 20V, _I4 = 3A

The power receiver controller 310 calculates powers P ₁ -P ₄ for the four PDO1-PDO4, respectively.
_P1 = _V1 * _I1 =15W
_P2 = _V2 * _I2 =27W
_P3 = _V3 * _I3 =36W
_P4 = _V4 * _I4 =60W

In this example, the powers P ₂ , P ₃ , and P ₄ of the three PDO2, PDO3, and PDO4 exceed the minimum required power P _MIN , so they are candidates for selection.

Here, for PDO4, its power _P4 exceeds the maximum required power _PMAX , so the current _I4 is corrected to _I4 '=45W/20V=2.25A. PDO4 after current modification is shown as PDO4' in FIG.

In the case of voltage priority, PDO4' having the maximum voltage value is selected from among PDO2, PDO3 and PDO4', and PDO4' is transmitted to power supply device 200 as RDO. PDO4' is also selected in the case of power priority.

After selecting one PDO from among a plurality of PDOs based on the minimum required power P _MIN , if the power of the selected PDO exceeds the maximum required power P _MAX , the current value is corrected. good too.

The advantage of Modification 1 becomes clear by comparison with the following comparative techniques. In the comparative technique, those PDOs whose power P _i exceeds the maximum required power P _MAX are excluded from the candidates. In this case, PDO4 is excluded from the candidates and PDO3 is selected. That is, although the power supply device 200 has a maximum power supply capacity of 60W, the actual power supply is P ₃ =36W.

On the other hand, in Modification 1, since RDO is determined after correcting PDO4, it is possible to supply power at V ₄ ×I _RQ =20V×2.25A=45W.

(Modification 2)
In Modification 2, the memory 320 holds the maximum current I _MAX that the power receiving device 300 can sink, in addition to the minimum required power P _MIN and the maximum required power P _MAX .

When there is a PDOj for which the current I exceeds the maximum current _IMAX , the power receiving controller 310 modifies the current _Ij to _IMAX . The power _Pj " of PDOj" after modification is calculated as _Pj "= _Vj * _IMAX . When finally selecting PDOj", the RDO becomes ( _Vj , _IMAX ).

FIGS. 6A and 6B are diagrams for explaining the operation of the power supply system 100 according to Modification 2. FIG. The minimum required power P _MIN is 27W and the maximum required power P _MAX is 45W. Also assume that the maximum current I _MAX is 3A.

In FIG. 6A, the PDO list 206 includes PDO1 and PDO2.
PDO1: _V1 =5V, _I1 =5A
PDO2: _V2 =12V, _I2 =5A

In this example, the currents _I1 , I2 of PDO1, _PDO2 both exceed the maximum current _IMAX , so PDO1, PDO2 are modified as follows.
PDO1″: _V1 =5V, _I1 =3A
PDO2": _V2 = 12V, _I2 = 3A

The power receiving controller 310 then calculates powers P ₁ ″ and P ₂ ″ for the modified PDO1″ and PDO2″.
_P1 ″=15W
_P2 ″=36W

In this case, since only P ₂ ″ exceeds the minimum required power P _MIN , PDO 2 ″ is selected and RDO (12 V, 3 A) is sent to power supply device 200 .

In the example of FIG. 6(b), the PDO list 206 includes PDO1-PDO3.
PDO1: _V1 =5V, _I1 =5A
PDO2: _V2 =12V, _I2 =5A
PDO3: _V3 =20V, _I3 =5A

In this example, the currents I ₁ , I ₂ and I ₃ of PDO1-PDO3 all exceed the maximum current I _MAX . Also, PDO3 exceeds the maximum required power P _MAX .

If the current _Ij of PDOj exceeds both the maximum current _IMAX and _Ij '= _PMAX / _Vj , it is modified to the lesser of _IMAX and _Ij '. Therefore, PDO1-PDO3 are modified as follows.
PDO1″: _V1 =5V, _I1 =3A
PDO2": _V2 = 12V, _I2 = 3A
PDO3': _V3 = 20V, _I3 = 2.25A

The power receiving controller 310 then calculates the powers P ₁ ″, P 2 ″, P ₃ ′ for the modified PDO1″, _PDO2 ″, and PDO3′.
_P1 ″=15W
_P2 ″=36W
_P3 ' = 45W

In the case of voltage priority, PDO3' is selected and transmitted to the power supply device 200 as RDO. PDO3' is similarly selected in the case of power priority.

(Modification 3)
Memory 320 may further retain the requested voltage range of power receiving device 300 . For example, the required voltage range is defined by at least one of a minimum voltage V _MIN as its lower limit and a maximum voltage V _MAX as its upper limit, or both.

The receiving controller 310 excludes PDOs whose voltage V is outside the required voltage range V _MIN to V _MAX .

FIG. 7 is a diagram explaining the operation of the power supply system 100 according to Modification 3. As shown in FIG. In the example of FIG. 7, the minimum value V _MIN of the required voltage range is 9V, and the maximum value V _MAX is 15V. The PDO list is the same as in FIG. 6(b). For PDO3′, the voltage V ₃ =20V is excluded because it is outside the required voltage range, and PDO2″ becomes the RDO.

(Modification 4)
In the description so far, the PDO of the power supply device 200 has been determined by specifying the voltage value V, but may be determined as the voltage range VR. Such a PDO is called a variable PDO. The power receiving controller 310 calculates the product of the minimum value of the voltage range VR and the current I as the power P for the variable PDO.

FIG. 8 is a diagram explaining the operation of the power supply system 100 according to Modification 4. As shown in FIG. In the example of FIG. 8, the PDO list 206 includes PDO1-PDO3. PDO3 is a variable PDO, and the voltage range _VR3 is 15-20V.
PDO1: _V1 =5V, _I1 =3A
PDO2: _V2 = 20V, _I2 = 2.25A
PDO3: _VR3 = 15-20V, _I3 = 2.5A

The powers P ₁ -P ₃ of PDO1-PDO3 are calculated as follows.
_P1 = 5V x 3A = 15W
_P2 = 20V x 2.25A = 45W
_P3 = 15V x 2.5A = 37.5W

Powers P ₂ and P ₃ of PDO2 and PDO3 are greater than P _MIN and less than P _MAX . For power priority mode, PDO2, which is 45W, is selected.

In the voltage priority mode, the minimum value of the voltage range VR is used, and the voltage _V3 of PDO3 is treated as 15V. Since V ₂ >V ₃ , PDO2 is selected even in the voltage priority mode.

(Other modifications)
In the embodiments, the USB PD standard has been exemplified as one of the applications of the present invention, but the present invention is applicable to other standards having protocols similar to the USB PD standard and USB PD standards that will be formulated in the future. It can also be applied to the next-generation standard of

Although the present invention has been described using specific terms based on the embodiments, the embodiments merely show the principles and applications of the present invention, and the embodiments are defined in the scope of claims. Many modifications and changes in arrangement are permitted without departing from the spirit of the present invention.

REFERENCE SIGNS LIST 100 power supply system 102 adapter 106 USB cable 200 power supply device 201 control circuit 202 power supply circuit 204 power supply side controller 206 PDO list 400 electronic device 402 load 404 receptacle 300 power receiving device 301 control circuit 302 battery 304 charging circuit 306 power supply circuit 308 DC/DC converter 310 power receiving side controller 320 memory

Claims (12)

A control circuit for a power receiving device that receives power from a power feeding device,
a memory holding the minimum required power P _MIN ;
receiving from the power supply device a list of first data defining combinations of voltages V and currents I that the power supply device is capable of supplying; a controller that calculates a power P that is the product of I, selects the first data such that the power P is greater than the minimum required power P _MIN , and transmits second data based on the selected first data to the power supply device; ,
with
the memory further holds a maximum required power P _MAX ;
The controller corrects the current to I'= _PMAX /V when the power P, which is the product of the voltage V of the first data and the current I, exceeds the maximum required power _PMAX . . The controller selects the first data having the maximum power P when there are a plurality of the first data in which the power P, which is the product of the voltage V and the current I, exceeds the minimum required power P _MIN . 2. A control circuit as claimed in claim 1. The controller selects the first data having the maximum voltage V when there are a plurality of the first data in which the power P, which is the product of the voltage V and the current I, exceeds the minimum required power P _MIN . 2. A control circuit as claimed in claim 1. The controller selects the first data with the maximum power P when there are a plurality of the first data in which the power P, which is the product of the voltage V and the current I, exceeds the minimum required power P _MIN . 2. The control circuit according to claim 1, wherein a mode and a voltage priority mode for selecting the first data having the maximum voltage V are selectable. the memory further holds a maximum current _IMAX ;
5. The controller corrects the current I of the first data to the maximum current _IMAX when there is the first data in which the current I exceeds the maximum current _IMAX . A control circuit according to any one of A control circuit for a power receiving device that receives power from a power feeding device,
a memory holding the minimum required power P _MIN ;
receiving from the power supply device a list of first data defining combinations of voltages V and currents I that the power supply device is capable of supplying; a controller that calculates a power P that is the product of I, selects the first data such that the power P is greater than the minimum required power P _MIN , and transmits second data based on the selected first data to the power supply device; ,
with
the memory further holds a maximum current _IMAX ;
A control circuit, wherein the controller modifies the current I of the first data to the maximum current I _MAX when the first data exists in which the current I exceeds the maximum current I _MAX . the memory further holds a voltage range required by the power receiving device;
5. The control circuit according to claim 1, wherein said controller excludes said first data in which said voltage V is out of said voltage range. 8. When the range of the voltage V is defined in the first data, the controller sets the power P to the product of the minimum value of the range of the voltage V and the current I. A control circuit according to any one of 9. The control circuit according to claim 1, wherein the control circuit is monolithically integrated on one semiconductor substrate. 10. The control circuit according to any one of claims 1 to 9, which corresponds to the USB PD standard. A power receiving device comprising the control circuit according to claim 1 . A method of negotiation between a power source and a power receiving device, comprising:
holding a minimum required power P _MIN and a maximum required power P _MAX in a memory of the power receiving device;
holding, in a memory of the power supply device, a list of first data defining combinations of voltage V and current I that can be supplied by the power supply device;
transmitting the first data list from the power supply device to the power reception device;
The power receiving device calculates, for each of the first data included in the list, a power P that is the product of a voltage V and a current I included therein, and the power P is greater than the minimum required power P _MIN for the first data included in the list. selecting data and transmitting second data based on the selected first data to the power feeding device;
when the power P, which is the product of the voltage V of the first data and the current I , exceeds the maximum required power P _MAX , modifying the current to I′=P _MAX /V;
A method of negotiation, comprising:

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