Apparatus for measuring bio-information and a method for error compensation thereof

What is claimed is: 1 . An apparatus for measuring bio-information, the apparatus comprising: a heart rate sensor unit configured to measure heart rates by receiving a light that has entered and come out from skin; an acceleration sensor unit configured to output a step count by measuring the step count of a wearer; a display unit configured to display the measured heart rates and step count; and a wrist-wearable connection unit configured to electrically connect the heart rate sensor, the acceleration sensor unit and the display unit. 2 . The apparatus of claim 1 , wherein the heart rate sensor unit includes, a light source unit configured to emit a linear light source, a light receiving unit configured to receive the light that has entered and come out from the skin from the light emitted from the light source, and a controller configured to detect the heart rates from a quantity of light received by the light receiving unit. 3 . The apparatus of claim 2 , wherein the light source unit includes, an LED (Light Emitting Diode) configured to emit a light of point light source, a curved light guide of a particular curvature radius configured to advance the emitted light to a particular direction, a plurality of V-shaped patterns configured to emit a light to a particular direction by refracting the emitted light, and a reflective plate configured to reflect a light emitted to an outside from the light guide into an interior of the light guide. 4 . The apparatus of claim 3 , wherein the LED uses a yellowish green color light source. 5 . The apparatus of claim 2 , wherein the light receiving unit includes, a first light receiving unit arranged at an upper left surface based on a lengthwise direction of the light source, a second light receiving unit arranged at an upper right surface based on a lengthwise direction of the light source, a third light receiving unit arranged at a bottom left surface based on a lengthwise direction of the light source, and a fourth light receiving unit arranged at a bottom right surface based on a lengthwise direction of the light source. 6 . The apparatus of claim 2 , wherein the light receiving unit includes, a photodetector configured to receive a light that has entered and come out of skin from a light emitted from the light source unit, and a light receiving house configured to wrap the photodetector and to gradually broaden at an entrance toward a skin contact surface. 7 . The apparatus of claim 3 , wherein the plurality of V-shaped patterns tapers off at a spacing of adjacent patterns as being distanced from the LED. 8 . The apparatus of claim 1 , wherein the connection unit is a wrist band type connector unit of elastic material. 9 . The apparatus of claim 1 , wherein the connection unit is a wrist watch type, wrist-attachable connector unit. 10 . A method for error compensation in a heart rate sensor including a first light receiving unit arranged at an upper left surface of a line light source, a second light receiving unit arranged at an upper right surface of the line light source, a third light receiving unit arranged at a bottom left surface of the line light source, and a fourth light receiving unit arranged at a bottom right surface of the line light source, the method comprising: detecting an error by comparing light signals received by the first to fourth light receiving units; multiplying a predetermined weight to a greater light signal as a result of comparison of the light signals when the error is generated; and adding a size of a light signal multiplied by the weight to a size of a light signal not multiplied by the weight. 11 . The method of claim 10 , wherein the error includes a first error, which is a difference between a first signal, which is a sum of light signals received by the first and second light receiving units and a second signal, which is a sum of light signals received by the third and fourth light receiving units, a second error, which is a difference between a third signal, which is a sum of light signals received by the first and third light receiving units and a fourth signal, which is a sum of light signals received by the second and fourth light receiving units, and a third error, which is a difference between a fifth signal, which is a sum of light signals received by the first and fourth light receiving units and a sixth signal, which is a sum of light signals received by the second and third light receiving units. 12 . The method of claim 11 , wherein the step of multiplying a predetermined weight to a greater light signal as a result of comparison of the light signals when the error is generated includes, multiplying a predetermined weight to a greater signal between the first and second signals when the first error is generated, multiplying a predetermined weight to a greater signal between the third and fourth signals when the second error is generated, and multiplying a predetermined weight to a greater signal between the fifth and sixth signals when the first error is generated. 13 . The method of claim 12 , wherein the method further comprises determining a greater value as a heart rate reference signal between a size of an optical signal multiplied by the weight and a size of an optical signal not multiplied by the weight. 14 . A method for error compensation in a heart rate sensor including a first light receiving unit arranged at an upper left surface of a line light source, a second light receiving unit arranged at an upper right surface of the line light source, a third light receiving unit arranged at a bottom left surface of the line light source, and a fourth light receiving unit arranged at a bottom right surface of the line light source, the method comprising: detecting an error by comparing light signals received by the first to fourth light receiving units; multiplying a predetermined weight to a greater light signal as a result of comparison of the light signals when the error is generated; and adding a size of a light signal multiplied by the weight to a size of a light signal not multiplied by the weight. 15 . The method of claim 14 , wherein the step of detecting an error by comparing light signals received by the first to fourth light receiving units includes determining a light receiving unit having received a largest size of optical signal by comparing a first error, which is a difference between a first signal, which is a sum of light signals received by the first and second light receiving units and a second signal, which is a sum of light signals received by the third and fourth light receiving units, a second error, which is a difference between a third signal, which is a sum of light signals received by the first and third light receiving units and a fourth signal, which is a sum of light signals received by the second and fourth light receiving units, and a third error, which is a difference between a fifth signal, which is a sum of light signals received by the first and fourth light receiving units and a sixth signal, which is a sum of light signals received by the second and third light receiving units.