阅读说明：本技术 一种转置混联电容阵列结构的设计方法 (Design method of transposed series-parallel capacitor array structure ) 是由 张瑞智 殷一文 张鸿 李嘉琪 于 2019-03-26 设计创作，主要内容包括：本发明公开的一种转置混联电容阵列结构的设计方法,在实现给定的电压转换比例时,所需的单位电容的数目更少,实现了更小的芯片面积。同时由于更少的电容需要的控制开关也更少,显著降低了电路的开关损耗,从而提高了DC-DC的效率。本发明在低功耗,高精度的开关电容DC-DC设计场合非常适用。(The design method of the transposed series-parallel capacitor array structure disclosed by the invention has the advantages that the number of required unit capacitors is less when a given voltage conversion proportion is realized, and the smaller chip area is realized. Meanwhile, fewer control switches are needed by fewer capacitors, so that the switching loss of the circuit is remarkably reduced, and the efficiency of DC-DC is improved. The invention is very suitable for the design occasion of the switched capacitor DC-DC with low power consumption and high precision.)

1. A design method of a transposed series-parallel capacitor array structure is characterized by comprising the following steps;

step 1, converting and scaling an input target voltage into a simplest fraction form, wherein the simplest fraction form is as follows;

a[i]/b[i]；

wherein, i is an initialization subscript, and the initial value of i is set to 0;

step 2, updating i to be i +1, and executing subsequent steps 3-6 according to the updated value of i;

step 3, carrying out remainder taking operation on b [ i-1 ]/ai [ i-1], and assigning the obtained remainder to ai;

a[i]＝MOD(b[i-1]/a[i-1])

step 4, assigning the value of a [ i-1] to b [ i ];

b[i]＝a[i-1]

step 5, adopting a lower rounding operation to lower and round the value of the fraction b [ i-1]/a [ i-1] to obtain a numerical value which is recorded as ci ];

c[i]＝INT(b[i-1]/a[i-1])

step 6, judging whether a [ i ] in the step 3 is equal to 1, and executing a step 7 when a [ i ] is equal to 1; otherwise, jumping to the step 2;

step 7, connecting bi unit capacitors in series to form an initial capacitor array;

step 8, connecting c [ i ] capacitors in parallel at two ends of the initial capacitor array;

step 9, transposing the capacitor array obtained in the step 8 to obtain a transposed capacitor array of the capacitor array;

step 10, updating i to be i-1;

step 11, judging whether i obtained in the step 10 is equal to 0, and if i is not equal to 0, jumping to the step 7; when i is equal to 0, obtaining a capacitor array in a charging state;

and step 12, transposing the capacitor array in the charging state to obtain the capacitor array in the discharging state.

2. The method for designing the transposed series-parallel capacitor array structure of claim 1, wherein the capacitor array is transposed in step 9 by the following method;

the capacitors connected in series in the capacitor array are changed into being connected in parallel, and the capacitors connected in parallel in the capacitor array are changed into being connected in series, so that the transposed capacitor array of the capacitor array is obtained.

3. The method of claim 1, wherein the design method of the transposed series-parallel capacitor array structure,

arranging a control switch on the capacitor array in the charging state or the capacitor array in the discharging state to obtain a switched capacitor array;

in a charging state, the switched capacitor array is connected to an input voltage source in a charging state capacitor array connection mode; in the discharge state, the switched capacitor array is connected to the load in a manner that the capacitor array is connected in the discharge state.

Technical Field

The invention belongs to the technical field of integrated circuits, and particularly relates to a design method of a transposed series-parallel capacitor array structure.

Background

With the rise of the internet of things technology, wireless sensors are increasingly popular in the fields of intelligent buildings, industrial control, health monitoring and the like. Typically, batteries are the energy source for these sensors, but the batteries have a limited useful life and therefore need to be replaced or recharged, and the batteries can add significant size and cost to the sensor.

One effective way to address the limited battery power is to collect energy in the environment surrounding the sensor, such as: light, vibration, temperature difference and the like, and converts the light, the vibration, the temperature difference and the like into electric energy to supply power to the sensor, so that continuous energy can be supplied to the sensor. The power management circuit is an indispensable module in the energy collection system, and converts the collected electric energy into a stable power supply to supply power to the sensor.

Mainstream power management circuits can be implemented using an inductance-based DC-DC converter, a linear regulator, or a switched capacitor DC-DC converter. Inductance-based DC-DC converters are efficient at high currents, but they require a large off-chip inductance, and therefore they do not meet the size requirements for compact energy collection. The linear voltage regulator has a relatively small area and can be fully integrated in a standard CMOS integrated circuit process, but the output voltage provided by the linear voltage regulator cannot be higher than the input voltage, and in addition, the efficiency of the linear voltage regulator is reduced along with the increase of the input-output voltage difference. The switched capacitor DC-DC converter has a high conversion efficiency at low current operation and can be fully integrated into a standard CMOS process. The switch capacitor DC-DC has very wide application prospect in low-power consumption application occasions such as energy collection and the like.

In recent years, most of the reported topologies for switched capacitor DC-DC include: basic Series-Parallel Matrix structures (Basic Series-Parallel to Matrix of Capacitors), Partial Arbitrary Matrix structures (Partial Arbitrary Matrices), and General transposed Series-Parallel structures (General transposed Series-Parallel).

Fig. 1 is a schematic diagram of a basic series/parallel matrix structure, which has m × l capacitors, each having the same size. In a charging state, m rows of capacitors are connected in parallel and then connected to an input voltage source, and each row of capacitors is formed by connecting l capacitors in series; in a discharging state, the capacitors which are originally connected in series in each column are connected in parallel to form a row, m rows of capacitors are obtained, and the m rows of capacitors are connected in series to be connected to an output end. Thus, the voltage conversion from input to output is completed, and the voltage conversion ratio of the capacitor array can be obtained by the voltage division relation of the capacitors as follows:

FIG. 2 is a diagram showing a part of an arbitrary matrix structure, which is common to allEach capacitor is equal in size. In a charging state, n columns of capacitors are connected in parallel and then connected to an input voltage source, and the number of the capacitors in each column is arbitrary; in the discharging state, all capacitors which are originally connected in series in each column are connected in parallel to form a row, n rows of capacitors are obtained, and the n rows of capacitors are connected in series to be connected to the output end. Thus, the voltage conversion from input to output is completed, and the voltage conversion ratio of the capacitor array can be obtained by the voltage division relation of the capacitors as follows:

fig. 3 is a general transpose series/parallel structure diagram, and the capacitance connection mode is the same as part of any matrix structure, but the difference is that: in a partially arbitrary matrix, each column capacitor in a charging state and each row capacitor in a discharging state are integrated, wherein the capacitors can only be used in the row or the column, so that the number of capacitors in each column or row is not variable; in the general transpose series/parallel structure diagram, each capacitor can be freely connected to any column or row, so that the number of capacitors in each column or row can be changed. When the voltage conversion ratio is finely adjusted, for example, 2.2 is switched to 2.25, a row of branches formed by connecting 4 capacitors in series are required to be added to replace the original branches formed by connecting 5 capacitors in series in part of any matrix structure; the universal transposition series/parallel structure only needs to remove one capacitor from a branch consisting of 5 capacitors connected in series to obtain 4 branches with capacitors connected in series, so that the number of the needed capacitors is saved. Likewise, the voltage conversion ratio of the universal transpose series/parallel configuration is:

the basic series/parallel matrix structure is developed to a universal transposition series/parallel structure, the flexibility of the connection mode of the capacitor array is improved, more voltage conversion ratios can be realized by the same number of capacitors, and the utilization efficiency of the capacitors is improved. However, the capacitor connection modes of these structures are still not flexible enough, and in a charging state or a discharging state, the capacitors in the single capacitor branch circuits are all in a series connection mode, so that the flexibility of the capacitor connection mode is restricted, the utilization efficiency of the capacitors is low, and the chip area occupied by the capacitor array is large.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a design method of a transposed series-parallel capacitor array structure, the connection mode of the capacitor array structure designed by the method is more flexible, the number of capacitors required by a given conversion proportion is greatly reduced, and simultaneously, the utilization efficiency of the capacitors and the conversion efficiency of DC-DC are greatly improved.

The invention is realized by the following technical scheme:

a design method of a transposed series-parallel capacitor array structure comprises the following steps;

step 1, converting and scaling an input target voltage into a simplest fraction form, wherein the simplest fraction form is as follows;

a[i]/b[i]；

wherein, i is an initialization subscript, and the initial value of i is set to 0;

step 2, updating i to be i +1, and executing subsequent steps 3-6 according to the updated value of i;

step 3, carrying out remainder taking operation on b [ i-1 ]/ai [ i-1], and assigning the obtained remainder to ai;

a[i]＝MOD(b[i-1]/a[i-1])

step 4, assigning the value of a [ i-1] to b [ i ];

b[i]＝a[i-1]

step 5, adopting a lower rounding operation to lower and round the value of the fraction b [ i-1]/a [ i-1] to obtain a numerical value which is recorded as ci ];

c[i]＝INT(b[i-1]/a[i-1])

step 6, judging whether a [ i ] in the step 3 is equal to 1, and executing a step 7 when a [ i ] is equal to 1; otherwise, jumping to the step 2;

step 7, connecting bi unit capacitors in series to form an initial capacitor array;

step 8, connecting c [ i ] capacitors in parallel at two ends of the initial capacitor array;

step 9, transposing the capacitor array obtained in the step 8 to obtain a transposed capacitor array of the capacitor array;

step 10, updating i to be i-1;

step 11, judging whether i obtained in the step 10 is equal to 0, and if i is not equal to 0, jumping to the step 7; when i is equal to 0, obtaining a capacitor array in a charging state;

and step 12, transposing the capacitor array in the charging state to obtain the capacitor array in the discharging state.

Preferably, the specific method for transposing the capacitor array in step 9 is as follows;

the capacitors connected in series in the capacitor array are changed into being connected in parallel, and the capacitors connected in parallel in the capacitor array are changed into being connected in series, so that the transposed capacitor array of the capacitor array is obtained.

Preferably, a control switch is arranged on the capacitor array in the charging state or the capacitor array in the discharging state to obtain a switched capacitor array;

in a charging state, the switched capacitor array is connected to an input voltage source in a charging state capacitor array connection mode; in the discharge state, the switched capacitor array is connected to the load in a manner that the capacitor array is connected in the discharge state.

Compared with the prior art, the invention has the following beneficial technical effects:

according to the design method of the transposed series-parallel capacitor array structure disclosed by the invention, under the charging and discharging states, each row of capacitors of the transposed series-parallel capacitor array structure is not limited to a full-series connection mode any more, so that the connection mode of the capacitors is more flexible, and the utilization efficiency of the capacitors is higher. Compared with a basic series-parallel structure, a partial arbitrary matrix structure and a universal transposition parallel/series structure, the capacitor array designed by the method has fewer unit capacitors when a given voltage conversion ratio is realized, and smaller chip area is realized under the condition that the unit capacitor area is constant. Meanwhile, fewer control switches are needed by fewer capacitors, so that the switching loss of the circuit is remarkably reduced, and the efficiency of DC-DC is improved. The invention is very suitable for the design occasion of the switched capacitor DC-DC with low power consumption and high precision.

Drawings

FIG. 1 is a schematic diagram of a basic series/parallel matrix structure;

FIG. 2 is a diagram of a conventional arbitrary matrix capacitor array;

fig. 3 is a structure diagram of a conventional general transpose series/parallel capacitor array;

FIG. 4 is a flow chart of a transposed series-parallel capacitor array design method of the present invention;

FIG. 5 is a diagram of a transposed series-parallel capacitor array for achieving 7/11 voltage conversion ratios according to the present invention;

FIG. 6 is a simulation waveform of a transposed mixed-connected switched capacitor DC-DC of the present invention implementing 7/11 voltage conversion ratio;

FIG. 7 is a comparison of a conventional switched capacitor configuration and the 7/11 voltage conversion ratio of the present invention;

FIG. 8 is a diagram of a capacitor array structure with c 3 capacitors connected in parallel across the initial capacitor array of the present invention;

FIG. 9 is a diagram of a transposed capacitor array structure of the capacitor array of FIG. 8;

FIG. 10 is a diagram of a capacitor array of FIG. 9 with c 2 capacitors connected in parallel across the capacitor array;

FIG. 11 is a diagram of a capacitor array structure with c [1] capacitors connected in parallel across the transposed capacitor array of the capacitor array of FIG. 10;

FIG. 12 is a diagram of a transposed capacitor array structure of the capacitor array of FIG. 11;

FIG. 13 is a diagram of a capacitor array configuration in a charged state in accordance with the present invention;

FIG. 14 is a diagram of a capacitor array structure in a discharge state according to the present invention.

Detailed Description

The present invention will now be described in further detail with reference to the attached drawings, which are illustrative, but not limiting, of the present invention.

As shown in fig. 4, a design method of a transposed series-parallel capacitor array structure includes two stages, namely a scaling stage and a capacitor mapping stage, and includes the following specific steps;

scale conversion stage

Step 1, converting and scaling the input target voltage into a simplest fraction form, and recording the simplest fraction as ai/bi.

Wherein, i is an initialization subscript, and the initial value of i is set to 0.

And step 2, updating i to be i +1, and executing subsequent steps 3-6 according to the updated value of i.

And 3, carrying out remainder operation (MOD) on the b [ i-1]/a [ i-1], and assigning the obtained remainder to a [ i ].

a[i]＝MOD(b[i-1]/a[i-1])

And 4, assigning the value of a [ i-1] to b [ i ].

b[i]＝a[i-1]

And 5, adopting an rounding-down operation (INT) to round down the fraction b [ i-1]/a [ i-1] to obtain a numerical value c [ i ].

c[i]＝INT(b[i-1]/a[i-1])

Step 6, judging whether ai in the step 3 is equal to 1, and when ai is equal to 1, ending the proportional transformation stage and entering a capacitance mapping stage; otherwise, jumping to step 2, repeating steps 2-6 until a [ i ] is equal to 1, and ending the loop.

Capacitive mapping phase

And 7, according to the parameter bi obtained in the scaling process, serially connecting bi unit capacitors to form an initial capacitor array, wherein the capacitor array is a two-port network, and subsequent capacitor mapping is operated on the basis of the initial capacitor array.

And 8, connecting c [ i ] capacitors in parallel at two ends of the initial capacitor array.

Step 9, transposing the capacitor array obtained in the step 8 by the capacitor array, wherein the specific method is as follows;

the capacitors connected in series in the capacitor array are changed into a parallel relation, and the original capacitors connected in parallel are changed into a series relation, so that the transposed capacitor array of the capacitor array is obtained.

And step 10, updating i to be i-1, and according to the updated value of i.

And 11, judging whether i obtained in the step 10 is equal to 0 or not, if i is not equal to 0, jumping to the step 7, executing the steps 7-11 until i is equal to 0, and ending the circulation to obtain the capacitor array in the charging state.

And step 12, transposing the capacitor array in the charging state to obtain the capacitor array in the discharging state.

Inputting a voltage conversion ratio to be realized, and obtaining the capacitor array in the corresponding charging state and discharging state.

And step 13, reasonably adding a control switch on the basis of the obtained capacitor array in the charging state or the capacitor array in the discharging state to obtain a switched capacitor array. By controlling the switching of the switch, the following effects can be achieved.

In a charging state, the switched capacitor array is connected to an input voltage source in a connection mode of the charged capacitor array; in the discharge state, the switched capacitor array is connected to the load in the form of a discharge state capacitor array connection.

This achieves a switched capacitor DC-DC of the required voltage conversion ratio.

According to the transposed parallel-serial capacitor array structure provided by the invention, each branch of the capacitor array can adopt a parallel-serial connection mode in the charging state and the discharging state of the switched capacitor, so that the flexibility of capacitor array connection is improved, and more various voltage conversion ratios can be realized.

The design method of the transposed series-parallel capacitor array structure provided by the invention has the advantage of high efficiency when the transposed series-parallel capacitor array structure designed by the method is applied to occasions needing to finely adjust the voltage conversion ratio of the switched capacitor DC-DC. The structure of the invention greatly reduces the number of capacitors required compared with the traditional switched capacitor structure when a given voltage conversion ratio is realized, thereby greatly reducing the required number of switches. Reducing the number of capacitors and switches can significantly reduce the switching losses of the circuit, thereby improving the efficiency of the DC-DC.