NO316002B1 - Method and apparatus for generating sound effects - Google Patents

Description

SOUND MANIPULATION

This invention generally relates to an electronic device including means for visual or audio playback and the use of a sensor in such equipment.

Portable music players have become increasingly popular in recent years, from relatively large CD players to small MP3 players in mobile phones, PDAs (Personal Digital Assistants) etc., or have been designed to connect to such. With its growing popularity, the demand for other offerings than just playing music has also increased, such as the simulation of "scratching", which was originally introduced by disk jockeys who moved LP records back and forth over a selected section of music, thus creating a rhythmic sound effect that became popular in certain types of music.

Players of the above type are normally expensive and, like mobile phones and PDAs, can be provided with PIN codes or other methods to personalize the equipment or reduce the chances of theft.

The biometrics market is developing rapidly, and the industry is becoming increasingly normalized. In order for biometrics to penetrate the consumer market, however, great demands are placed on both price and functionality (for example, power requirements).

Today, finger scanners are typically pure reading devices, and thus the responsibility for handling the case is left to the host. Thus, the requirements are strict for implementation in an electronic device, for example a mobile phone, MP3 player or PDA, with regard to processing power and memory for the signal processing. Nevertheless, when these mature and are eventually implemented in finger scanners, these requirements will still apply.

International patent application No. PCT/NO98/00182 describes a stripe sensor that requires the finger to be moved over the scanner, which then samples information about the finger surface and generates a two-dimensional representation of the finger.

For strip-shaped finger scanners, the user must be allowed to drag their finger across the scanner at varying speeds. If the finger scanner samples at a fixed rate this provides a method to detect the velocity across the scanner and align the axes of the rows sampled so that the axes of the aligned image are equal and linear.

Examples of such speed meters are discussed in the international patent applications PCT/NO01/00241 and PCT/NO01/00242, while PCT7NO01/00243 and PCTVNOOl/00244 describe sensors that provide motion sensitivity in more than one direction.

The presence of sensors of the above type that are not in use all the time leaves room for additional functions. It is an object of the present invention to use an existing sensor for popular functions such as sound manipulation in a music player of any available type, for manipulation of music or sounds stored in the memory of the electronic device.

The purpose of this invention is achieved by means of a device as described above characterized by the fact that it comprises a sensor with means for real-time measurements of the movement of a surface in relation to the sensor, where the device is provided with means to change the played music in relation to selected characteristics depending on the measured movement, and in the use of a sensor provided with real-time measurements of movement of a surface in relation to the sensor, where the sensor is provided with an electronic device and the electronic device is provided with means for playing music

The invention will be described below with reference to the attached drawings, which illustrate the invention by means of examples.

Figure 1 illustrates a substantially linear fingerprint scanner.

Figure 2 illustrates use of the fingerprint scanner for navigation purposes i

at least two directions.

Figure 3 illustrates a possible division of measured directions into categories.

Figure 4 illustrates a simple sequence for carrying out the method according to the invention.

This invention describes an additional functionality for a finger scanner or the like that uses the structure of the finger. While a so-called "touchpad" detects a finger moving across its surface, this method detects the movement of the sensor area relative to the finger. For a strip-shaped finger scanner, this requires some additional elements, while with a matrix-shaped finger scanner, the already existing sensor elements may be sufficient. Since this mode would be active for a significant part of the usage time for a mobile phone or PDA, it is important that the number of elements is reduced to a minimum, so that the need for power supply, processor and memory at the host is low. Figure 1 illustrates the sensor according to international patent application No. PCT7NO98/00182 comprising sensor elements with speed compensation 2.3. In addition to detecting movement along the axis of the motion compensation sensors 2,3, the neighboring sensor elements 4 can be used to detect angular movements, and sensitivity along the array can be provided by having the sensor elements detect the presence of a finger. Thus, an essentially linear sensor can be sensitive to movement in at least 4 directions. Figure 2 illustrates an essentially linear finger scanner which has the ability to detect movements in two dimensions, as described in PCT/NO01/00244. The principle of the pointer function is to determine the direction of the finger moving and then calculate the distance based on the speed of the finger.

With reference to Figure 3, an omnidirectional functionality is illustrated indicating a categorization of directions, in this case 12 categories. According to one embodiment of the invention, each category can produce different sound effects. The categories can, if the electronic device is equipped with a screen, be indicated to improve the system's functionality. Some of the categories can also give commands to the system, such as on/off the sound effect function. Use of a similar system for feeding information into a system is described in the simultaneously filed international patent application No. PCT/NO02/00468.

According to a preferred embodiment of the invention, the sensitivity can be limited to movements along an axis, so that the "scratching" effect is achieved by passing the finger back and forth over the sensor, or simply as a volume control, Since the above-mentioned sensors provide an opportunity for for real-time speed measurements, acoustic signals stored in the electronic device can be played at a pitch proportional to the measured speed, thus corresponding directly to the disc jockey's movements on the turntable. By adding filters to the signal, almost any effect can be achieved.

In more detail, to simulate the "scratching" based on the output signal from the sensor unit and the velocity and direction calculations, the following two operations must be performed: 1. A digitally stored sample or reproduction of the "scratch" sound must be played while the finger is moved over the sensor. The pitch should be adjusted according to the speed of the finger. The ratio between the pitch and the speed can be one

fixed constant or a parameter that can be changed by the end user.

2. The current position in the played music must be moved forward. And backwards, depending on the direction of the finger movements, with displacement based on speed and time or the length of the finger swipe. The relationship between the displacement in position in the music and the length of the finger movement can also be a fixed constant or a parameter that can be changed by the end user.

Figure 3 indicates a simple procedure for using the sensor to change the pitch of the played music, in which the change in the pitch of the music is changed by a factor df, which is proportional to the speed v of the finger over the sensor. The constant k can be chosen depending on the effect.

Several extensions to the scratch simulation can be enabled to encourage future DJs to explore other effects based on this method. For example, different modes can be selected by the user where effects typical of synthesizers can be changed by moving the finger over the sensor unit. As mentioned before, different effects can be associated with different directions across the sensor.

Using a sensor unit that is more sensitive to movement in two dimensions enables more advanced manipulation of the music, such as shifting the pitch along one axis while simultaneously adjusting the pitch levels along a second axis.

This invention is described primarily with a view to a finger scanner of the type described in international patent application No. PCT/NO98/00182, and thus primarily to capacitance measurements on a finger surface. However, it is clearly possible for the invention to be applied to other types of sensors, such as thermal sensors, within the scope of the present requirements.

The invention is also primarily described in relation to finger scanners of the above type. Other speed correction means are, however, also possible in some cases, such as rolling drums consisting of a drum that is rotated by the user. This, however, has a number of disadvantages, since the drum is a mechanically complicated structure which is sensitive to dust and wear. In addition, the drum can only measure speeds along one axis, while the sensors above, particularly as described in PCT/NOO1/00244, can ensure measurement of movement in two directions.

Claims (10)

1. Electronic device comprising means for playing audio or video signals, characterized in that it also includes a sensor for measuring selected properties of a finger surface, means for real-time measurements of the movements of the finger surface relative to the sensor, and means for changing the reproduced signal according to the measured movements. 2. Device according to claim 1, where the sensor is a finger scanner designed for scanning the surface of a finger. 3. Device according to claim 1, where the sensor is arranged to measure movement in two dimensions. 4. Device according to claim 1, where the speed of the surface in relation to the sensor is measured. 5. Device according to claim 4, where the pitch of the music is changed by a factor that is proportional to the speed of the surface in relation to the sensor. 6. Application of a sensor for measuring selected properties of a finger surface, where the sensor is provided with devices for real-time measurements of the movement of the finger surface in relation to the sensor, in addition to an electronic device provided with means for playing music. 7. Application according to claim 6, where the sensor is a finger scanner. 8. Application according to claim 6, where the sensor is designed to measure movement in two dimensions. 9. Application according to claim 6, where the speed of the surface is measured and the music is changed in relation to the speed. 10. Application according to claim 9, where the pitch of the music is changed by a factor that is proportional to the speed.