WO2014086228A1

WO2014086228A1 - Method and system for passing personalized parameters of novel module

Info

Publication number: WO2014086228A1
Application number: PCT/CN2013/087174
Authority: WO
Inventors: 徐永松
Original assignee: 宁波舜宇光电信息有限公司
Priority date: 2012-12-03
Filing date: 2013-11-14
Publication date: 2014-06-12
Also published as: CN102999472A; CN102999472B

Abstract

A method for passing personalized parameters of a module, comprising the following steps: 1) using a reading device to read unique product IDs of module products; 2) confirming corresponding personalized parameters of a module according to the product IDs; and 3) passing the personalized parameters of the module to a client using an information passing device. The method can overcome the defects of small storage space, slow storage speed and small storage data amount in the traditional storage solution, and further meet the requirements of high-end customers for image quality, thereby reducing costs, and improving the product yield.

Description

Novel module personalized parameter transmission method and system

The invention relates to a method for acquiring OTP data of a high pixel module, in particular to a novel module grouping parameter transmission method and system. Background technique

At present, when the camera module manufacturer produces the camera module, it generates some personalized parameters/data for each module's characteristics, such as module ID, Lens ID, motor ID, AWB, shading and AF, etc. The data, currently using the OTP/EERPOM scheme, stores the data generated by each camera module into the OTP/EERPOM. When the mobile terminal uses the camera module, it first reads the data from the OTP/EERPOM and then applies it to the sensor. The purpose of this is to set a personalized parameter of each camera module, let the back-end system read it, and then set it in a targeted manner, which can greatly improve the consistency of the module. The disadvantage is that the storage space is limited, the amount of data that can be stored is relatively small, the batch is burned due to the stability of the production light source, etc. At the same time, the information is not comprehensive enough due to the limitation of the OTP space, and the quality of the camera module is often not satisfied by the high-pixel high-end customers. The requirements, such as some image effects tests (such as MTF-Focusing/MTF check/Macro MTF/Blemsih/Defective pixels, etc.) and test images, the client can not track the comprehensive information of each camera module. Secondly, it takes more man-hours and more cost to store to OTP/EPPROM, and it may cause the camera module to be scrapped due to poor programming. For example, when the customer temporarily notices that some parameters are temporarily changed, if OTP is used. The way, because it is one-off, it cannot be changed, and there is no flexibility in production. Based on the limitations of current solutions and the increasing requirements of clients, we need a new way of personalizing parameter delivery to solve the above problems. Summary of the invention

The main object of the present invention is to solve the problem that the OTP storage space is insufficient or the OTP burn defect rate is difficult to control and more flexible to define the consistency of the high pixel module. The solution is as follows: A new type of module personalization A parameter transfer system, including a server for storing module personalization data, an information transfer device for connecting to a server and reading server information, a barcode or serial number set on a module product, and a reading device for reading a barcode or serial number The barcode or the serial number on the module product corresponds to a unique product ID, and the server stores the module personalized data corresponding to the product ID.

Obtaining the product ID includes identifying the barcode on the module product by means of a dedicated identifier, or reading the serial number set inside the module sensor or within the module OTP by the reading device.

The information delivery device that obtains server related information includes an MES system, a mobile storage, or other computer terminal.

A method for personalizing parameter transfer by using a novel module personalized parameter transfer system according to any of the preceding claims, comprising the following steps:

1) using the reading device to read the unique product ID of the module product;

2) Confirm the corresponding module personalization parameters according to the product ID;

3) Transfer the module personalization parameters to the client using the information transfer device.

In the step 1), if the module product is provided with a barcode, the module product ID on the barcode is recognized by the special identifier; if the module has no barcode, the ID serial number set inside the module sensor is read or The product ID is read by the serial number in the module OTP.

In the step 1), the file name of the server storage module personalized data is named according to the module serial number on the barcode, the serial number set inside the sensor, or the serial number written in the OTP.

The information transfer device obtains corresponding data including the following methods: 1) downloading corresponding module personalized data through the MES system; 2) obtaining through mobile storage; 3) transmitting data by email or the like. The server storage data is stored in the form of a database.

The beneficial effects of the present invention are as follows:

1) This new type of personalized parameter transmission method can solve the shortcomings of small storage space, slow storage speed and low storage data volume of traditional storage solutions, and largely meet the requirements of high-end customers for image quality;

2) It can avoid data corruption caused by instability of the production line source;

3) The traditional OTP method is one-time programming. If the data fails, the module will be scrapped, and the new method does not require OTP programming of the module. Therefore, the yield is greatly improved and the cost is reduced;

4) Personalized parameters can be covered to all sensors: Traditional methods, due to the size of OTP, therefore, only some SENSOR can use OTP, such as SONY, part of SENSOR of APTINA, part of SOV of OVT does not have enough OTP Space, which makes it impossible to burn individualized parameters, can only set the initialization parameters by statistically determining the average value, so that the evaluation can satisfy the consistency of most modules, but 5% of the parameters. On the other hand, the module with the 5% parameter below does not meet the requirements;

5) It can reduce the cost: Traditional modules like SONY, OVT, if there is very little OTP space, if the customer requests to improve, you need to add EEPROM to store, which will greatly increase the module composition. Therefore, using this method can significantly reduce costs. DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic illustration of an embodiment of the invention. detailed description

1 is a schematic diagram of an embodiment of the present invention. As shown in the figure, a module manufacturer first establishes a data storage system, which includes a test station, a database, and a network shared hard disk, and uses a server to store the storage space. The server stores data in the form of a database. In theory, such a storage space can be expanded indefinitely, and can continuously meet the different needs of different customers. Each camera module has a unique fuse ID that identifies the different modules. When the module manufacturer produces the test data and images generated by each camera module (as before, the fuse ID is stored on the server. For this way, the storage speed will be faster, and the data can be saved to the server after it is generated. There is no need to burn to OTP/EEPROM, and the module will not be scrapped due to programming failure.

When the client needs to use it, the data can be obtained in the following ways: 1) If the module is labeled with 2D BARCODE, the module ID can be identified by a special identifier, and then the data is obtained by the corresponding ID; 2) by reading Take the ID serial number inside the SENSOR, and then find the corresponding data for the serial number; 3) Obtain the data by reading the internal OTP serial number and then the corresponding serial number file; There are also several ways to obtain the corresponding data: 1) download corresponding module personalization data through MES system; 2) obtain through mobile storage; 3) transfer data by email or the like.

The module needs to complete the following steps during production:

Generate the production data and pictures required by the customer from the test machine, and send them to the data storage system (hereinafter referred to as the system) with the fuse ID of the module;

The system stores the production data in the database and stores the image on the network shared hard disk; the system also generates an XML file, which contains all the production data and the network address pointing to the storage location of the image;

The system passes the XML file to the client.

When obtaining data, only the XML file will be sent to the client through the pre-established MES system website; or sent to the client as a database file via mail or other media.

Correspondingly, the client needs to use the production data as follows: According to the 2D barcode, obtain the file name, and then obtain the data from the website database according to the file name, and download it to the mobile phone, so that each time the module is Initialize

According to the FUSE ID number read from the module, and read the data in the database with the ID number as the file name, and download it to the mobile phone for initialization;

According to the ID number in the read SENSOR OTP, and read the data in the database with this ID number as the file name, and download it to the mobile phone for initialization.

Claims

claims

1. A new type of module personalized parameter transmission system, characterized by: including a server that stores module personalized data, an information transmission device used to connect to the server and read server information, a barcode or barcode set on the module product, or Serial number and a reading device for reading barcodes or serial numbers. The barcode or serial number on the module product corresponds to a unique product ID, and the server stores module personalized data corresponding to the product ID.

2. The new module personalized parameter transfer system according to claim 1, characterized in that: Obtaining the product ID includes identifying the barcode on the module product through a special identifier, or reading the settings through a reading device The serial number inside the module sensor or module OTP.

3. The new module personalized parameter transmission system according to claim 1, characterized in that: the information transmission equipment for obtaining server-related information includes an MES system, a mobile storage or other computer terminals.

4. A method for transferring module personalized parameters using the new module personalized parameter transfer system according to any one of the preceding claims, which is characterized in that it includes the following steps:

1) Use a reading device to read the unique product ID of the module product;

2) Confirm the corresponding module personalized parameters according to the product ID;

3) Use information transmission equipment to transmit module personalized parameters to the client.

5. The new module personalized parameter transmission method according to claim 4, characterized in that, in step 1), if the module product is provided with a barcode, the module product on the barcode is identified through a special identification device. ID; If the module does not have a barcode, read the product ID by reading the ID serial number set inside the module sensor or by reading the serial number in the module OTP.

6. The new module personalized parameter transfer method according to claim 4, characterized in that in step 1), the file name of the server storing module personalized data is based on the module serial number on the barcode, It is named by the serial number set inside the sensor or the serial number written into the OTP.

7. The new module personalized parameter transmission method according to claim 4, characterized in that the information transmission device obtains the corresponding data by the following methods: 1) Downloading the corresponding data through the MES system Corresponding module personalized data; 2) Obtain through mobile storage; 3) Transfer data through email, etc.

8. The new module personalized parameter transfer method according to claim 4, characterized in that the server stores data in the form of a database.