Distance measuring equipment

A distance measuring equipment which is useful in, for example, a collision prevention system wherein a laser beam is forward emitted from a vehicle to measure a distance between the vehicle and a forward vehicle, and an alarm is produced when the present vehicle abnormally approaches the forward vehicle. In the distance measuring equipment, when a correction instruction signal is supplied, a distance calculating circuit first drives an optically shielded light emitting element for correction to emit light, and produces a correction signal on the basis of a signal input into an adder connected to a light receiving element. Thereafter, the distance calculating circuit drives a light emitting element for measurement to emit light, and produces a distance measurement signal with referring the correction signal.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The invention relates to a distance measuring equipment (so-called laser 
radar) which is useful in, for example, a collision prevention system 
wherein a laser beam is forward emitted from a vehicle to measure a 
distance between the vehicle and a forward vehicle, and an alarm is 
produced when the present vehicle abnormally approaches the forward 
vehicle. 
2. Description of the Related Art 
A distance measuring equipment of this kind will be described with 
reference to FIG. 7. 
In FIG. 7, reference numeral 1 designates a clock signal generator which 
supplies a timing clock signal to various circuits, and 2 designates a 
light emission trigger signal generator which converts the clock signal 
supplied from the clock signal generator 1 into a light emission signal 
functioning as a trigger signal, on the basis of a control signal supplied 
from a distance calculating circuit 15 which will be described later. 
Reference numeral 3 designates a driving circuit which is powered by a 
power source circuit 4, and which, in response to the supply of the light 
emission signal from the light emission trigger signal generator 2, drives 
at each supply a light emitting element 5 to generate a laser beam. The 
power source circuit 4 supplies the power not only to the driving circuit 
3 but also to the other circuits. 
Reference numeral 6 designates a light transmitting lens through which the 
laser beam from the light emitting element 5 is output so as to diffuse 
away from the element 5 at a predetermined angle, and 8 designates a light 
emitting unit which comprises the driving circuit 3, the power source 
circuit 4, the light emitting element 5, the light transmitting lens 6, 
and the like. 
Reference numeral 9 designates a honeycomb filter which is disposed so as 
to cover the front surface of the incidence plane of a light receiving 
lens 10. Among light beams reflected by an object (not shown) which is in 
front of the equipment such as a forward vehicle (hereinafter, such an 
object is referred to as "forward object"), only light beams which are 
parallel to the optical axis of the light receiving lens 10 are allowed to 
pass through the lens, and light beams which are not parallel to the 
optical axis are disabled to pass the lens. Reference numeral 11 
designates a light receiving element which receives light beams converged 
by the light receiving lens 10 and converts them into an electric signal, 
12 designates an amplifier which amplifies the light reception signal from 
the light receiving element 11 and outputs the amplified signal, and 13 
designates a light receiving unit which comprises the honeycomb filter 9, 
the light receiving lens 10, the light receiving element 11, the amplifier 
12, and the like. 
Reference numeral 14 designates an adder. In the case where a period is 
defined between the supply of a control signal from the distance 
calculating circuit 15 and the next supply of the control signal, each 
time when the control signal is supplied, the adder 14 adds the waveform 
output from the amplifier 12 in the current period to that in the previous 
period so as to convert the light reception signal into a signal having an 
improved S/N ratio, and then outputs the signal. Specifically, when the 
control signal is supplied N times from the distance calculating circuit 
15 to the light emission trigger signal generator 2 and the adder 14, the 
light emitting element 5 emits a laser beam the corresponding number of 
times, i.e., N times, and waveforms respectively produced by the emitting 
operations and including the light reception signals output from the 
amplifier 12 are added to each other. When the adding operations are 
completed, the calculation result in the current period is binarized and 
then output. 
The distance calculating circuit 15 supplies to the light emission trigger 
signal generator 2 the control signal for causing the light emitting 
element 5 to emit light. Further, the distance calculating circuit 15 
instructs the adder 14 to conduct the adding operations, by means of the 
control signal. 
When receiving the waveform showing the binarized addition result from the 
adder 14, the distance calculating circuit 15 calculates the distance 
between the equipment and the forward object on the basis of the resulting 
waveform. Specifically, in the pulse string showing the addition result 
which has been binarized at predetermined temporal intervals, a first 
pulse having a width which is greater than a predetermined level is 
detected, and the distance is calculated on the basis of the period 
between the time when the control signal is output and that of the first 
pulse. 
Next, the operation of the equipment described above will be described. 
When the power source for the whole of the equipment is turned on, the 
distance calculating circuit 15 repeatedly outputs the control signal (see 
FIG. 8(A)) at intervals of a predetermined period T. Each time when the 
control signal is output, the light emitting element 5 generates a laser 
beam, and the laser beam is forward emitted through the light transmitting 
lens 6. 
The laser beam is reflected by the forward object to return to the 
equipment, and then detected by the light receiving element 11 through the 
light receiving lens 10. The output of the light receiving element 11 is 
supplied to the adder 14 via the amplifier 12. In the adder 14, the output 
from the amplifier 12 is divided for the predetermined period T, and, each 
time when a signal is newly obtained, the new signal is added to the 
signal of the previous period. In other words, the waveforms of N periods 
are added to each other (see FIG. 8(B)). 
This allows the weakened reflection beams, i.e., the laser beams to be 
extracted as the light reception signal from the output of the amplifier 
12, so that the laser beam is subjected to the signal processing. 
Then the adder 14 binarizes the addition result to convert it into a logic 
signal (see FIG. 8(C)). The logic signal is checked to see whether or not 
the probability of the period of the high level with respect to that of 
the low level is equal to or greater than 50% in a unit period which is 
obtained by further dividing the period T. If the probability is equal to 
or greater than 50%, periods t1 and t2 of the maximum pulse widths in the 
high-level periods wherein the probability is equal to or greater than 50% 
are detected (waveforms P1 and P2 in FIG. 8(D)). The detected data (see 
FIG. 8(D)) are supplied to the distance calculating circuit 15. 
As a result, the distance calculating circuit 15 calculates the distance 
between the forward object and the equipment on the basis of the temporal 
difference TO between the first timing P1, among the supplied data (see 
FIG. 8(D)), when the probability that the questioned pulse can be presumed 
a reflection signal is raised to 100%, and the timing when the distance 
calculating circuit 15 outputs the control signal. The calculated distance 
is supplied to an alarm judging circuit (not shown). When the distance 
enters a dangerous range, an alarm signal is produced. The second timing 
P2 when the probability is 100% is neglected. 
In such a distance measuring equipment, however, a large current must be 
supplied when the light emitting element 5 such as a laser diode emits a 
light beam, and the light receiving element is required to have a high 
sensitivity. Each time when the light emitting element 5 emits a light 
beam, therefore, electric noise (see the portion Q1 of FIG. 8(B)) is 
superposed as a DC component on the output signal which is supplied from 
the amplifier 12 to the adder 14. 
In the case where a signal (see the symbol Q2 of FIG. 8(B)) indicative of 
the reflection beam from the forward object and generated with being 
superposed on noise components close to white noise should originally be 
subjected to the signal processing so that the distance signal Td is 
detected as shown in FIG. 8(E), however, the adder 14 actually processes 
the noise portion Q1 as if it is a signal indicative of the reflection 
beam from the forward object. This results in that the distance is 
erroneously measured, thereby producing a problem in that the reliability 
of the measurement accuracy is lowered. 
This problem may be solved by shielding the whole of the circuits or by 
disposing a noise filter in the power source circuit. When such a 
countermeasure is taken, however, the number of electronic parts is 
increased and the area for mounting these parts is enlarged and hence 
there arise further problems in that the production cost is increased, and 
that the equipment is too large to be used in a practical use. 
SUMMARY OF THE INVENTION 
The invention has been made in view of these problems. It is an object of 
the invention to provide a distance measuring equipment having a simple 
configuration in which noise components produced by light emission of a 
light emitting element can be eliminated and only a reflection signal is 
detected so that the accuracy of measuring a distance is improved. 
In attaining the above object, the invention provides a distance measuring 
equipment including: a light emitting element for measurement; an 
optically shielded light emitting element for correction; timing means for 
generating a timing signal; light emission trigger signal generating means 
for receiving the timing signal from the timing means to generate a 
trigger signal; driving means for receiving the trigger signal from the 
light emission trigger signal generating means to drive the light emitting 
element for measurement to emit light; a light receiving element for 
receiving light emitted from the light emitting element for measurement 
and reflected by a forward object; adding means for conducting an adding 
operation a predetermined number of times on an output signal including a 
light reception signal from the light receiving element, during a period 
between reception of the timing signal from the timing means and next 
reception of the timing signal, and for binarizing and normalizing an 
addition result; and distance calculating means for calculating a distance 
between the equipment and the forward object on the basis of a waveform 
signal supplied from the adding means and the timing signal output from 
the timing means, wherein the timing means drives the optically shielded 
light emitting element for correction to emit light, through the light 
emission trigger signal generating means and the driving means, and 
corrects a signal due to the light reception signal from the light 
receiving element with using an input to the adding means at this time as 
a correction signal. 
The invention also provides a distance measuring equipment including: a 
light emitting element; driving means for intermittently driving the light 
emitting element; switch means which is connected in parallel to the light 
emitting element; timing means for generating a timing signal; light 
emission trigger signal generating means for supplying the timing signal 
from the timing means to the driving means as a trigger signal; a light 
receiving element for receiving light emitted from the light emitting 
element and reflected by a forward object; adding means for, each time 
when receiving plural times the timing signal supplied from the timing 
means, conducting an adding operation on an output signal including the 
light reception signal from the light receiving element, in a period 
immediately before the reception, and for binarizing and normalizing an 
addition result; and distance calculating means for calculating a distance 
between the equipment and the forward object on the basis of a waveform 
signal supplied from the adding means and the timing signal output from 
the timing means, wherein the switch means is switched to be conductive in 
synchronization with the adding operation in the adding means, thereby 
setting the light emitting element to be a non-light emitting state, and a 
signal due to the light reception signal from the light receiving element 
is corrected with using an input to the adding means at this time as a 
correction signal.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
First Embodiment 
Hereinafter, an embodiment of the invention will be described with 
reference to FIG. 1. 
Components in FIG. 1 which have the same configuration as or equivalent to 
that described in conjunction with FIG. 7 are designated by the same 
reference numerals and their description is omitted. Only the 
configuration which is different from that of FIG. 7 will be described. 
In FIG. 1, reference numeral 3' designates a driving circuit, and 15' 
designates a distance calculating circuit. In these circuits, the 
functions described below are added to those of the driving circuit 3 and 
the distance calculating circuit 15 in the equipment of FIG. 7. 
Furthermore, a shielded light emitting element 20 is additionally 
disposed. Specifically, when a correction instruction signal is externally 
supplied through a terminal X, the distance calculating circuit 15' 
supplies to the driving circuit 3' a signal for driving only the shielded 
light emitting element 20 to emit light. Thereafter, the distance 
calculating circuit 15' outputs a trigger signal, i.e., a light emission 
start signal. The driving circuit 3' drives the light emitting element 20 
to emit light during only the period when the correction instruction 
signal is supplied through the terminal X (or during a predetermined 
period after the start of the supply). 
The light emitting element 20 is completely enclosed by a light shield 
member 21 and is the same in kind as the light emitting element 5. The 
adder 14, the light emission trigger signal generator 2, and the distance 
calculating circuit 15' may be configured by a hardware. It is a matter of 
course that these circuits may be configured by a software by using a CPU 
constituting a microcomputer. This is applicable also to second and third 
embodiments which will be described later. 
The operation of the above configuration will be described with reference 
to FIG. 2 on the assumption that the adder 14, the light emission trigger 
signal generator 2, and the distance calculating circuit 15' are 
configured by a CPU. 
When the power source of the equipment is turned on, the process advances 
to step ST100. If the correction instruction signal is supplied through 
the terminal X, steps ST101, ST102 and ST103 are repeatedly executed. 
Namely, the distance calculating circuit 15' controls the driving circuit 
3' so that only the light emitting element 20 for correction is set to be 
the drive-enabled state, and supplies the light emission start signal to 
the light emission trigger signal generator 2. The light emission trigger 
signal generator 2 supplies N times the trigger signals to the driving 
circuit 3' which in turn drives the light emitting element 20 for 
correction to emit light N times. The adder 14 divides the output from the 
amplifier 12 for the predetermined period T (which uses the light emission 
start signal as the reference) and sequentially adds the waveform of a 
newly obtained period to the output waveform of the previous period. Since 
light is not emitted to the outside during this operation, no light 
reception signal is produced in the portion Q2 due to the light beams 
reflected from the forward object, and a large DC component is produced 
only in the portion Q1 due to electric noise (FIG. 8(F)). 
In step ST104, the addition result is binarized, and then subjected to a 
processing in which pulses of a high level are counted in each minute unit 
period. The count results are stored as Nn (n=0, 1, 2, . . . , m). 
Then the process advances to step ST105 in which the light emission trigger 
signal generator 2 causes the light emitting element 5 for measurement to 
periodically emit light. This light emission is conducted by repeatedly 
executing steps ST106 and ST107 in the same manner as that in steps ST102 
and ST103. In step ST108, pulses of a high level are counted in each 
minute unit period in the same manner as step ST104. The count results are 
stored as Sn (n=0, 1, 2, . . . , m). In this case, light is emitted to the 
outside, and therefore a DC component is produced in both the portion Q1 
due to electric noise and the portion Q2 due to the light beams reflected 
from the forward object (FIG. 8(B)). 
The obtained values Sn (n=0, 1, 2, . . . , m) are subjected in step ST109 
to the calculation of .alpha.n=0.5.times.(Sn/Nn) (n=0, 1, 2, . . . , m). 
According to this calculation, 0.5 is obtained for all periods where Sn 
and Nn are equal to each other, and a predetermined value is obtained for 
only a period where Sn is greater than Nn. In other words, the portion Q2 
of FIG. 8(B) which is different from the corresponding portion of FIG. 
8(F) is extracted to obtain the output of FIG. 8(E). 
In step ST110, the value obtained in step ST109 is compared with a 
predetermined value, for example, 0.5. If the obtained value is equal to 
or less than the predetermined value, it is judged that the signal is due 
to noises, and the process returns to step ST100. If the obtained value 
exceeds the predetermined value, it is judged that the signal includes 
light beams reflected from the forward object, and the process advances to 
next step ST111. 
In step ST111, on the basis of the light reception signal which has been 
normalized at a probability that a high level is obtained at each minute 
period as shown in FIG. 8(E), the period Td is detected which elongates 
until the instant when the normalized light reception signal in response 
to the control signal rises to exceed the predetermined value. The 
distance between the forward object and the equipment is calculated 
according to the expression of 3.times.10.sup.8 .times.(Td/2). Thereafter, 
the process returns to step ST100. 
Second Embodiment 
Hereinafter, another embodiment of the invention will be described with 
reference to FIG. 3. 
Components in FIG. 3 which have the same configuration as or equivalent to 
that described in conjunction with FIG. 7 are designated by the same 
reference numerals and their description is omitted. Only the 
configuration which is different from that of FIG. 7 will be described. 
In FIG. 3, reference numeral 15' designates a distance calculating circuit. 
In the circuit, the function described below is added to that of the 
distance calculating circuit 15 in the equipment of FIG. 7. Furthermore, a 
switch circuit 22 is additionally disposed. Specifically, when a 
correction instruction signal is externally supplied through a terminal X 
after the power source of the equipment is turned on, the distance 
calculating circuit 15' supplies a signal for making the switch circuit 22 
turn on (conductive) so that the both terminals of the light emitting 
element 5 is short-circuited (in an equivalent circuit). Thereafter, the 
distance calculating circuit 15' outputs a light emission start signal. 
The operation of the above configuration will be described with reference 
to FIG. 4. 
When the power is turned on, the process advances from step A to step 
ST200. If it is judged that the correction instruction signal is supplied 
through the terminal X, the distance calculating circuit 15' sets the 
input and output terminals of the switch circuit 22 to be electrically 
connected to each other or the on state (step ST201) so that, even when 
the driving circuit 3' supplies a drive signal to the light emitting 
element 5, the light emitting element 5 does not emit light, and the 
current from the power source circuit 4 flows directly into the driving 
circuit 3'. 
Thereafter, the process advances to step ST202 in which the distance 
calculating circuit 15' supplies the light emission start signal to the 
light emission trigger signal generator 2, and the light emission trigger 
signal generator 2 supplies the trigger signal to the driving circuit 3'. 
The current (which is equal in level to that used in the case where the 
light emitting element 5 is to be driven) from the power source circuit 4 
flows directly into the driving circuit 3' through the switch circuit 22, 
or without passing through the light emitting element 5. 
The adder 14 divides in step ST203 the output from the amplifier 12 for the 
predetermined period T (which uses the light emission start signal as the 
reference) and sequentially adds the waveform of a newly obtained period 
to the output waveform of the previous period (this operation is the same 
as that shown in FIG. 8(B)). 
In step ST204, it is judged whether the processing of steps ST202 and ST203 
is repeated N times or not. If the repeat number is less than N, the 
process returns to step ST202. If the repeat number reaches N, the result 
is divided in each unit period (which is sufficiently shorter than the 
period T), and the effective value of the waveform in each period is 
calculated. The effective values are stored as Nn (n=0, 1, 2, . . . , m). 
In step ST205, in response to a signal from the distance calculating 
circuit 15', the input and output terminals of the switch circuit 22 are 
set to be the off state. This allows the light emitting element 5 to emit 
light when the light emission start signal is supplied. 
Then the process advances to step ST206 in which the light emission trigger 
signal generator 2 supplies the light emission start signal to the driving 
circuit 3' so that the light emitting element 5 emits light. The light 
reception signal is processed in step ST207 in the same manner as step 
ST203. Specifically, in step ST207, the addition result is divided in each 
unit period which is sufficiently shorter than the period T, and the 
effective value of the waveform in each period is calculated in the same 
manner as step ST203. The effective values are stored as Sn (n=0, 1, 2, . 
. . , m). In step ST208, thereafter, the same process as that of step 
ST204 is conducted. 
In step ST209, the stored effective values which has been divided in each 
unit period or the effective values of the first periods are sequentially 
subjected to a division operation, and the division result is multiplied 
by a coefficient of 0.5. In other words, the calculation of 
.alpha.n=0.5.times.(Sn/Nn) (n=0, 1, 2, . . . , m) is done. 
In step ST210, the maximum value of the values .alpha.n which have been 
obtained in step ST209 for each unit value is compared with a 
predetermined value, for example, 0.5. If the maximum value is less than 
the predetermined value, it is judged that the signal is due to noise, and 
the process returns to step ST200. If the maximum value exceeds the 
predetermined value, it is judged that the signal includes light beams 
reflected from the forward object, and the process advances to next step 
ST211. 
If the maximum value exceeds in step ST210 the predetermined value, on the 
basis of the light reception signal which has been normalized at a 
probability that a high level is obtained at each minute period as shown 
in FIG. 8(E), the period Td is detected which elongates until the instant 
when the normalized light reception signal in response to the control 
signal rises to exceed the predetermined value. The distance between the 
forward object and the equipment is calculated according to the expression 
of 3.times.10.sup.8 .times.(Td/2). Thereafter, the process returns to step 
ST200. 
If the correction instruction signal is not supplied through the terminal X 
in step ST200, it is judged that the value Nn has been already calculated, 
and the process jumps to step ST205. 
Third Embodiment 
Hereinafter, still another embodiment of the invention will be described 
with reference to FIG. 5. 
Components in FIG. 5 which have the same configuration as or equivalent to 
that described in conjunction with FIG. 7 are designated by the same 
reference numerals and their description is omitted. Only the 
configuration which is different from that of FIG. 7 will be described. 
In FIG. 5, reference numeral 3' designates a driving circuit, and 15' 
designates a distance calculating circuit. In these circuits, the 
functions described below are added to those of the driving circuit 3 and 
the distance calculating circuit 15 in the equipment of FIG. 7. 
Furthermore, a shielded light emitting element 20 and an automatic gain 
control (AGC) circuit 23 are additionally disposed. Specifically, when a 
correction instruction signal is externally supplied through a terminal X, 
the distance calculating circuit 15' supplies to the driving circuit 3' a 
signal for driving only the shielded light emitting element 20 to emit 
light. Thereafter, the distance calculating circuit 15' outputs a light 
emission start signal. The driving circuit 3' can drive the light emitting 
element 20 to emit light during only the period when the correction 
instruction signal is supplied, in accordance with the light emission 
start signal which is a trigger signal from the light emission trigger 
signal generator 2. The light emitting element 20 is completely enclosed 
by a light shield member 21 so that light emitted in the light emitting 
operation is prevented from leaking through the light transmitting lens 6. 
The light emitting element 20 is the same in kind as the light emitting 
element 5. The AGC circuit 23 controls the voltage supplied to the driving 
circuit 3' from the power source circuit 4 so as to control the emission 
outputs of the light emitting elements 20 and 5. 
The operation of the above configuration will be described with reference 
to FIG. 6. 
When the power source of the equipment is turned on, the process advances 
from step A to step ST300. When the correction instruction signal is 
supplied through the terminal X, the process further advances to step 
ST301 in which the distance calculating circuit 15' controls the driving 
circuit 3' so that only the light emitting element 20 for correction is 
set to be the drive-enabled state. The distance calculating circuit 15' 
supplies the light emission start signal to the light emission trigger 
signal generator 2, and the light emission trigger signal generator 2 
supplies the trigger signal to the driving circuit 3' at intervals of the 
period T. As a result, the driving circuit 3' drives the light emitting 
element 20 for correction to emit light at intervals of the period T. 
After the light emitting element 20 emits light in step ST301, the process 
advances to step ST302. In step ST302, the adder 14 binarizes the output 
of the amplifier 12 with using a reference value of a predetermined level 
as the threshold, and counts pulses of a high level in each minute unit 
period (n=0, 1, 2, . . . , m). The count results are temporarily stored. 
In other words, the multiplication factor of a period which has a high 
level as a result of the binarization with respect to the minute unit 
period is calculated, and the calculation results are temporarily stored. 
The processing of steps ST301 and ST302 is repeated N times by passing 
through next step ST303. The final count results are stored as Nn (n=0, 1, 
2, . . . , m). 
Then the process advances to step ST304 in which the trigger signal from 
the light emission trigger signal generator 2 causes the light emitting 
element 5 for measurement to emit light at intervals of the period T. 
Signals due to light received by the light receiving element 11 are 
supplied to the adder 14 via the amplifier 12. In step ST305, pulses of a 
high level are counted in each minute unit period in the same manner as 
step ST302. The count results Sn (n=0, 1, 2, . . . , m) are temporarily 
stored at each time. After the processing of steps ST304 and ST305 is 
repeated N times, the process advances through step ST306 to step ST307. 
In step ST307, the calculation of .alpha.'n=(Sn/Nn)/N (n=0, 1, 2, . . . , 
m) is done on the calculated values Sn and Nn. 
In step ST308, the maximum value of the values .alpha.'n which has been 
obtained in step ST307 is compared with a predetermined value, for 
example, 0.3. If the maximum value is less than the predetermined value, a 
signal instructing the power source circuit 4 to raise the voltage 
supplied to the driving circuit 3' is issued from the AGC circuit 23 in 
step ST309. Thereafter, the process returns to step ST301. In other words, 
in this case, it is judged that the distance between the forward object 
and the equipment is long so that the emission outputs of the light 
emitting elements 20 and 5 is raised. 
If the maximum value of .alpha.'n is greater than the predetermined value 
of 0.3 in step ST308, the process advances to step ST310 in which the 
maximum value of .alpha.'n is compared with another predetermined value, 
for example, 0.7. If the maximum value is greater than the predetermined 
value, a signal instructing the power source circuit 4 to lower the 
voltage supplied to the driving circuit 3' is issued from the AGC circuit 
23 in step ST311. Thereafter, the process returns to step ST301. In other 
words, in this case, it is judged that the distance between the forward 
object and the equipment is short so that the emission outputs of the 
light emitting elements 20 and 5 is lowered. 
If the maximum value of .alpha.'n is in the range between predetermined 
values, for example, 0.3 to 0.7 (0.3.ltoreq..alpha.'n.ltoreq.0.7) in step 
ST310, it is judged that the signal includes light beams reflected from 
the forward object, and the process advances to next step ST312. 
In step ST312, the waveform binarized as shown in FIG. 8(C) is calculated 
on the basis of the periods of a high level per minute unit period, or in 
other words the multiplication factor of a period which has a high level 
with respect to the minute unit period is calculated. The period Td is 
calculated which elongates from the timing of rising of the trigger signal 
functioning as the light emission start signal to the timing of rising of 
the light reception signal. The distance is calculated according to the 
expression of 3.times.10.sup.8 .times.(Td/2), and the process then returns 
to step ST300. According to the distance measuring equipment of this 
embodiment, since the emission outputs of the light emitting elements 20 
and 5 are controlled by the AGC circuit 23, the measurement of a distance 
is performed with a higher accuracy. 
In the first to third embodiments described above, the correction 
instruction signal is externally supplied to the terminal X. 
Alternatively, the correction instruction signal may automatically be 
produced by the distance calculating circuit 15' (or the corresponding 
function of a microcomputer) when the power source of the equipment is 
turned on. It is a matter of course that, in the alternative, steps ST100, 
ST200 and ST300 in the flowcharts of the embodiments are eliminated. 
As described above, the invention can attain an effect that the accuracy of 
measuring a distance can be improved by configuring the equipment so as to 
perform simple signal processing at a reduced cost.