This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2019-166239, filed on Sep. 12, 2019, the entire contents of which are incorporated herein by reference.
Embodiments described herein relate to a semiconductor device and a voltage supplying method.
When plural power source voltage generators (VDD generators) in a semiconductor device are simultaneously trimmed, the trimming may be made inappropriate.
In one embodiment, a semiconductor device includes a reference voltage supply circuit configured to supply a first reference voltage and a second reference voltage. The device further includes a power source voltage supply circuit including a first power source voltage generator supplied with the first reference voltage and configured to generate a first power source voltage, and a second power source voltage generator supplied with the second reference voltage and configured to generate a second power source voltage, the power source voltage supply circuit being configured to supply the first power source voltage and the second power source voltage to a power source voltage line. The device further includes a voltage control circuit connected to the power source voltage line, and configured to control a value of the first reference voltage and a value the second reference voltage.
Embodiments will now be explained with reference to the accompanying drawings. In
The NAND chip 1 includes a plurality of input/output (I/O) pads 1a, RE and BRE (read enable) pads 1b and 1c, and an applied voltage pad 1d. The IO pads 1a are used for inputting commands from the tester 2 to the NAND chip 1, and outputting data from the NAND chip 1 to the tester 2. The RE pad 1b is used for supplying a RE signal from the tester 2 to the NAND chip 1. The BRE pad 1c is used for supplying a BRE signal from the tester 2 to the NAND chip 1. The applied voltage pad 1d is used for supplying an applied voltage Vapp from the tester 2 to the NAND chip 1.
The NAND chip 1 further includes a memory cell array 11 including a plurality of memory cells, a controller 12 that controls operations of the NAND chip 1, a reference voltage supply circuit 13, a power source voltage supply circuit 14, and a determination circuit 15. The power source voltage supply circuit 14 includes a plurality of VDD generators 14a to 14d. The NAND chip 1 further includes a power source voltage line L1, a reference voltage line L2, a reference voltage line L3, an applied voltage line L4, and a flag signal line L5.
The reference voltage supply circuit 13 supplies a reference voltage VrefIO as an example of a first reference voltage, and a reference voltage Vref as an example of a second reference voltage. The reference voltage VrefIO is supplied via the reference voltage line L2 to the VDD generator 14a that is arranged for the IO pads 1a. On the other hand, the reference voltage Vref is supplied via the reference voltage line L3 to the VDD generators 14b to 14d that are arranged for components other than the IO pads 1a. The VDD generator 14a for the IO pads 1a is an example of a first power source voltage generator, and the remaining VDD generators 14b to 14d are examples of a second power source voltage generator.
The power source voltage supply circuit 14 supplies a power source voltage VDD to the power source voltage line L1. In the present embodiment, the IO pads 1a, the RE pad 1b, and the BRE pad is are electrically connected to each other via the power source voltage line L1. The VDD generators 14a to 14d are electrically connected to each other via the power source voltage line L1. Further, the VDD generator 14a is electrically connected to the IO pads 1a, the RE pad 1b, and the BRE pad is via the power source voltage line L1. The VDD generator 14b is electrically connected to the controller 12 via the power source voltage line L1.
The VDD generator 14a is provided for the IO pads 1a, and generates the power source voltage VDD based on the reference voltage VrefIO, and supplies the generated voltage to the IO pads is (and also to the RE and BRE pads 1b and 1c). The power source voltage VDD from the VDD generator 14a is an example of a first power source voltage. The VDD generators 14b to 14d are provided for the components other than the IO pads 1a, generate the power source voltage VDD based on the reference voltage Vref, and supply the generated voltage to portions other than the IO pads 1a. The power source voltage VDD from the VDD generators 14b to 14d is an example of a second power source voltage. In the present embodiment, the power source voltage VDD from the VDD generator 14b is supplied to the controller 12, and the power source voltage VDD from the VDD generators 14c and 14d is supplied to arithmetic circuits in the NAND chip 1.
The determination circuit 15 compares the voltage on the power source voltage line L1 (power source voltage VDD) with the voltage on the applied voltage line L4 (applied voltage Vapp), and outputs a flag signal FLG indicating a result of the comparison to the flag signal line L5. For example, when the power source voltage VDD from the VDD generator 14a is supplied to the power source voltage line L1, the determination circuit 15 compares the power source voltage VDD from the VDD generator 14a with the applied voltage Vapp, and outputs the flag signal FLG indicating the comparison result. The applied voltage Vapp is an example of the voltage for comparison, and the flag signal FLG is an example a signal indicating the comparison result.
The controller 12 receives the flag signal FLG from the flag signal line L5, and controls the value of the reference voltage VrefIO and the value of the reference voltage Vref based on the flag signal FLG. In the present embodiment, trimming processing for the NAND chip 1 is performed by controlling the values of the reference voltages VrefIO and Vref. The tester 2 controls operations of the controller 12 in the trimming processing. The determination circuit 15 and the controller 12 are an example of a voltage control circuit.
Details of the controller 12, the reference voltage supply circuit 13, the power source voltage supply circuit 14, and the determination circuit 15, and details of the trimming processing will be described below with reference to
The reference voltage supply circuit 13 includes a comparator 13a, a MOS transistor 13b, a variable resistor 13c that is an example of a first variable resistor, a variable resistor 13d that is an example of a second variable resistor, and a fixed resistor 13e. The MOS transistor 13b, the variable resistor 13c, the variable resistor 13d, and the fixed resistor 13e are connected in series between an external voltage Vext and the ground voltage.
The comparator 13a has a first input terminal to which a constant voltage (e.g., 1.2 V) is supplied, a second input terminal connected to the node N3, and an output terminal that outputs a comparison result between an input voltage of the first input terminal and an input voltage of the second input terminal. The MOS transistor 13b is, for example, a pMOS, which has a gate terminal connected to the output terminal of the comparator 13a, a source terminal disposed on the external voltage Vext side, and a drain terminal disposed on the node N1 side.
The variable resistor 13c is provided for generating the reference voltage VrefIO at the node N1, and is arranged between the node N1 and the node N2. In the present embodiment, the value of the reference voltage VrefIO may be changed by changing the resistance value of the variable resistor 13c. The reference voltage supply circuit 13 of the present embodiment supplies the reference voltage VrefIO from the node N1 to the VDD generator 14a.
The variable resistor 13d is provided for generating the reference voltage Vref at the node N2, and is arranged between the node N2 and the node N3. In the present embodiment, the value of the reference voltage Vref may be changed by changing the resistance value of the variable resistor 13d. The reference voltage supply circuit 13 of the present embodiment supplies the reference voltage Vref from the node N2 to the VDD generators 14b to 14d.
The fixed resistor 13e is provided for giving an influence to the voltage of the node N3, and is arranged between the node N3 and the ground voltage. The voltage of the node N3 is supplied to the second input terminal of the comparator 13a.
Each of the VDD generators 14a to 14d is a unity gain buffer configured by an operational amplifier. Accordingly, the operational amplifier configuring each of the VDD generators 14a to 14d includes a first input terminal connected to the reference voltage supply circuit 13 to receive the reference voltage VrefIO or the reference voltage Vref, an output terminal connected to the determination circuit 15 to output the power source voltage VDD, and a second input terminal connected to this output terminal to configure a feedback circuit. The VDD generators 14a to 14d are arranged in parallel with each other between the reference voltage supply circuit 13 and the determination circuit 15.
The determination circuit 15 includes a comparator 15a. The comparator 15a includes a first input terminal to which the voltage of the power source voltage line L1 is supplied, a second input terminal to which the applied voltage Vapp is supplied, and an output terminal that outputs the flag signal FLG indicating a comparison result between an input voltage of the first input terminal and an input voltage of the second input terminal. The flag signal FLG of the present embodiment becomes 0 (low) when the voltage of the power source voltage line L1 is lower than the applied voltage Vapp and becomes 1 (high) when the voltage of the power source voltage line L1 is equal to or greater than the applied voltage Vapp. In
The controller 12 receives the flag signal FLG from the determination circuit 15 and controls, based on the flag signal FLG, the value of the reference voltage VrefIO and the value of the reference voltage Vref. Specifically, the controller 12 controls the value of the reference voltage VrefIO by outputting a control signal FIO<1:0> for controlling the resistance value of the variable resistor 13c and controls the value of the reference voltage Vref by outputting a control signal F<4:0> for controlling the resistance value of the variable resistor 13d.
When performing the trimming processing using the reference voltage Vref, the controller 12 operates in the following manner. When the flag signal FLG is low, the controller 12 counts up the value of the control signal F so that the resistance value of the variable resistor 13d increases with elapsing time. When the control signal F is transmitted to the variable resistor 13d, the resistance value of the variable resistor 13d increases with elapsing time. As a result, the value of the reference voltage Vref increases with elapsing time. Subsequently, when the flag signal FLG changes to high, the trimming processing using the reference voltage Vref terminates.
Similarly, when performing the trimming processing using the reference voltage VrefIO, the controller 12 operates in the following manner. When the flag signal FLG is low, the controller 12 counts up the value of the control signal FIO so that the resistance value of the variable resistor 13c increases with elapsing time. When the control signal FIO is transmitted to the variable resistor 13c, the resistance value of the variable resistor 13c increases with elapsing time. As a result, the value of the reference voltage VrefIO increases with elapsing time. Subsequently, when the flag signal FLG changes to high, the trimming processing using the reference voltage VrefIO terminates.
The trimming processing using the reference voltages Vref and VrefIO will be described in detail below.
The variable resistor 13c includes four MOS transistors T10, T11, T12, and T13, and three resistors R11, R12, and R13. The MOS transistors T10, T11, T12, and T13 are arranged in parallel with each other between the node N1 and the node N2. The resistor R11 is arranged between the MOS transistors T10 and T11. The resistor R12 is arranged between the MOS transistors T11 and T12. The resistor R13 is arranged between the MOS transistors T12 and T13.
As illustrated in
The controller 12 (
The variable resistor 13d includes four MOS transistors T20, T21, T22, and T23 and four resistors R20, R21, R22, and R23. The MOS transistors T20, T21, T22, and T23 are arranged in parallel with each other between the node N2 and the node N3. The resistor R20 is arranged between the node N3 and the MOS transistor T20. The resistor R21 is arranged between the MOS transistors T20 and T21. The resistor R22 is arranged between the MOS transistors T21 and T22. The resistor R23 is arranged between the MOS transistors T22 and T23.
As illustrated in
The controller 12 of the present embodiment outputs the control signal F for controlling the resistance value of the variable resistor 13d. The control signal F is a digital signal indicating a digital value corresponding to the resistance value of the variable resistor 13d and is input to the gate terminals of the MOS transistors T20 to T23. As a result, the resistance value of the variable resistor 13d changes to the digital value indicated by the control signal F, and the reference voltage Vref changes correspondingly. The reference voltage Vref corresponds to the above-described analog signal. In this manner, the variable resistor 13d converts the digital value indicating the value of the control signal F into the analog value indicating the value of the reference voltage Vref.
The fixed resistor 13e includes one resistor R30. The resistor R30 is arranged between the node N3 and the ground voltage. Two or more resistors may be provided in the fixed resistor 13e.
Next, the trimming processing using the reference voltages Vref and VrefIO will be described again with reference to
The trimming processing of the present embodiment includes first trimming processing to be performed using the reference voltage Vref and second trimming processing to be subsequently performed using the reference voltage VrefIO. In the first trimming processing, all the VDD generators 14a to 14d are trimmed using the reference voltage Vref. In the second trimming processing, only the VDD generator 14a among the VDD generators 14a to 14d is trimmed using the reference voltage VrefIO.
In the first trimming processing, the resistance value of the variable resistor 13c is fixed to zero and the resistance value of the variable resistor 13d is caused to increase with elapsing time. Accordingly, the value of the reference voltage Vref increases with elapsing time. On the other hand, since the variable resistor 13c is zero, the value of the reference voltage VrefIO becomes equal to the value of the reference voltage Vref (VrefIO=Vref). Accordingly, the reference voltage Vref that increases with elapsing time is supplied to the VDD generators 14b to 14d. The reference voltage VrefIO, which is the same as the reference voltage Vref, is supplied to the VDD generator 14a. That is, in the first trimming processing, the same reference voltage Vref is supplied to all the VDD generators 14a to 14d.
In the first trimming processing, all the VDD generators 14a to 14d are operated to perform trimming to 1.85 V. Specifically, by counting up the value of the control signal F, the reference voltage Vref is caused to increase with elapsing time and the power source voltage VDD to be input to the determination circuit 15 is caused to increase so as to reach 1.85 V. On the other hand, the applied voltage Vapp is set to 1.85 V. Accordingly, when the power source voltage VDD reaches 1.85 V, the value of the flag signal FLG changes from 0 to 1. In the first trimming processing, the value of the control signal F at the time when the power source voltage VDD has reached 1.85 V is determined as a trim value. The trim value is stored inside or outside the NAND chip 1.
In the second trimming processing, the value of the control signal F is fixed to the above-described trim value and, while the resistance value of the variable resistor 13d is fixed, the resistance value of the variable resistor 13c is caused to increase with elapsing time. Accordingly, the reference voltage VrefIO becomes higher than the reference voltage Vref (VrefIO>Vref), and the value of the reference voltage VrefIO increases with elapsing time. In the second trimming processing, the reference voltage VrefIO higher than the reference voltage Vref is supplied to the VDD generator 14a.
In the second trimming processing, only the VDD generator 14a among the VDD generators 14a to 14d is operated to perform trimming to 1.85 V. Specifically, by counting up the value of the control signal FIO, the reference voltage VrefIO is caused to increase with elapsing time and the power source voltage VDD to be input to the determination circuit 15 is caused to increase so as to reach 1.85 V. On the other hand, the applied voltage Vapp is set to 1.85 V. Accordingly, when the power source voltage VDD reaches 1.85 V, the value of the flag signal FLG changes from 0 to 1. In the second trimming processing, the value of the control signal FIO at the time when the power source voltage VDD has reached 1.85 V is determined as the trim value. The trim value is stored inside or outside the NAND chip 1.
Next, a comparative example of the NAND chip 1 of the first embodiment will be described. Advantages of the trimming processing of the first embodiment will be described through comparison between the first embodiment and the comparative example.
In the NAND chip 1 of this comparative example, the configuration illustrated in
The reference voltage supply circuit 13 of the comparative example does not include the variable resistor 13c. Accordingly, a node N2 of the reference voltage supply circuit 13 is electrically connected not only to VDD generators 14b to 14d but also to a VDD generator 14a. The reference voltage Vref is supplied to all the VDD generators 14a to 14d.
Each of
In the trimming processing (i.e., the first trimming processing) of the comparative example, all the VDD generators 14a to 14d are simultaneously trimmed in the state where the consumption current of the NAND chip 1 is zero. Therefore, when there is a difference in the value of the supplied power source voltage VDD among the VDD generators 14a to 14d, trimming suitable for the VDD generator supplying the highest power source voltage VDD is performed.
Accordingly, when the VDD generator 14a for the IO pads 1a supplies the highest power source voltage VDD, trimming suitable for the VDD generator 14a is performed (see
It is considered that the speed of input/output signals at the IO pads 1a increases as the generation of the NAND chip 1 advances. Accordingly, inappropriately trimming the VDD generator 14a for the IO pads 1a is not desired. On the other hand, simultaneously trimming a plurality of VDD generators is desired to efficiently perform the trimming processing.
Therefore, the trimming processing of the present embodiment includes the first trimming processing for simultaneously trimming all the VDD generators 14a to 14d and the second trimming processing for trimming only the VDD generator 14a for the IO pads 1a. This makes it possible to efficiently perform the trimming processing while appropriately trimming the VDD generator 14a for the IO pads 1a.
In the first trimming processing, the power source voltage VDD increases with elapsing time by counting up the control signal F. When the power source voltage VDD reaches the applied voltage Vapp (e.g., 1.85 V), the flag signal FLG changes from 0 to 1. In the first trimming processing, the value of the control signal F at the time when the power source voltage VDD has reached the applied voltage Vapp is determined as the trim value.
In the second trimming processing, the power source voltage VDD from the VDD generator 14a increases with elapsing time by counting up the control signal FIO while fixing the value of the control signal F to the trim value. When the power source voltage VDD reaches the applied voltage Vapp (e.g., 1.85 V), the flag signal FLG changes from 0 to 1. In the second trimming processing, the value of the control signal FIO at the time when the power source voltage VDD has reached the applied voltage Vapp is determined as the trim value.
As described above, the NAND chip 1 of the present embodiment includes the reference voltage supply circuit 13 that supplies the power source voltage Vref to the VDD generators 14b to 14d and also supplies the power source voltage VrefIO to the VDD generator 14a. Therefore, according to the present embodiment, it is possible to efficiently trim all the VDD generators 14a to 14d while appropriately trimming the VDD generator 14a. Therefore, the plurality of VDD generators 14a to 14d can be appropriately trimmed.
In the present embodiment, the power source voltage supply circuit 14 includes four VDD generators 14a to 14d, but may include N VDD generators where N is an integer of two or more. In this case, the trimming processing may include first trimming processing for trimming all the N VDD generators and second trimming processing for trimming only one of the N VDD generators. In the second trimming processing, two or more of the N VDD generators may be trimmed.
Although the VDD generator 14a for the IO pads 1a is subjected to the second trimming processing of the present embodiment, a VDD generator for anything but the IO pads 1a may be subjected to the second trimming processing.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel devices and methods described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the devices and methods described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2019-166239 | Sep 2019 | JP | national |