/ 
 
 TK 
 
 W 6169 
 
THE TELEPHONE. 
 
 A LECTUBE 
 
 ENTITLED 
 
 IN ELECTEIC TELEPHONY, 
 
 BY 
 
 PROFESSOR ALEXANDER GRAHAM ^ELL, 
 
 DELIVERED BEFORE 
 
 of Sktajrajjh 
 
 OCTOBER 31sT, 1877. 
 
 PUBLISHED BY THE SOCIETY,- - , ; , 
 
 AND EDITED BY 
 
 LIEUT.-COL. FRANK BOLTON, C.E , HON. SECRETARY, 
 
 AND 
 
 WILLIAM EDWARD LANGDON, ACTING SECRETARY. 
 
 ?tontion. 
 E. AND F. N. SPON, 46, CHARING CROSS. 
 
 Nrto |?orft: 
 44G, BROOME STREET. 
 
 1878. 
 
 Price One tilt ill ing //</ ^/'j-^ri/ 
 The right of translation and reproduction is 
 
EXTRACTS OF PROCEEDINGS 
 
 OF THE 
 
 SOCIETY OF TELEGRAPH ENGINEERS. 
 
 Special General Meeting, held at 25, Great George Street, West- 
 minster, on Wednesday, the 31st October, 1877. PROFESSOR 
 ABEL, C.B., F.R.S., President, in the Chair. 
 
 The PRESIDENT : Gentlemen, the Council of the Society of 
 Telegraph Engineers felt that they were sure of doing what the 
 members would consider right in summoning a special meeting for 
 the two-fold purpose of giving a welcome to Professor Bell to this 
 country and affording the Members an opportunity of hearing from 
 him an account, which he has been so good as to promise to give us, 
 of the nature, history, and development of, what may well be called, 
 one of the most interesting discoveries of our age. Our time is 
 very precious this evening. We all desire to hear everything 
 Professor Bell can tell us on this subject, and many gentlemen will 
 probably desire afterwards to ask questions or discuss the subject, 
 for I see present a great number of eminent scientific men. I will 
 not waste another moment, but at once call upon Professor Bell to 
 commence his discourse on the Electric Telephone. 
 
 RESEARCHES IN ELECTRIC TELEPHONY. 
 By PROFESSOR ALEXANDER GRAHAM BELL. 
 
 PROFESSOR BELL : Mr. President and Gentlemen of the Society 
 of Telegraph Engineers. It is to-night my pleasure, as well as duty, 
 to give you some account of the telephonic researches in which I 
 
 M175801 
 
''I : -VRESEAKCHES IN 
 
 have been so long engaged. Many years ago my attention was 
 directed to the mechanism of speech by my father, Alexander 
 Melville Bell, of Edinburgh, who has made a life-long study of the 
 subject. Many of those present may recollect the invention by my 
 father of a means of representing, in a wonderfully accurate 
 manner, the positions of the vocal organs in forming sounds. 
 Together we carried on quite a number of experiments, seeking to 
 discover the correct mechanism of English and foreign elements of 
 speech, and I remember especially an investigation in which we 
 were engaged concerning the musical relations of vowel sounds. 
 When vowel sounds are whispered, each vowel seems to possess a 
 particular pitch of its own, and by whispering certain vowels in 
 succession a musical scale can be distinctly perceived. Our aim 
 was to determine the natural pitch of each vowel ; but unexpected 
 difficulties made their appearance, for many of the vowels seemed to 
 possess a double pitch one due, probably, to the resonance of the 
 air in the mouth, and the other to the resonance of the air contained 
 in the cavity behind the tongue, comprehending the pharynx and 
 larynx. 
 
 I hit upon an expedient for determining the pitch which at that 
 time I thought to be original with myself. It consisted in vibrating 
 a tuning-fork in front of the mouth while the positions of the vocal 
 organs for the various vowel sounds were silently taken. It was 
 found that each vowel position caused the reinforcement of some 
 particular fork or forks. 
 
 I wrote an account of these researches to Mr. Alex. J. Ellis, of 
 London, whom I have very great pleasure in seeing here to-night. 
 In reply he informed me that the experiments related had already 
 been performed by Helmholtz, and in a much more perfect manner 
 than I had done. Indeed, he said that Helmholtz had not only 
 analysed the vowel sounds into their constituent musical elements, 
 but had actually performed the synthesis of them. 
 
 He had succeeded in producing, artificially, certain of the vowel 
 sounds by causing tuning-forks of different pitch to vibrate 
 simultaneously by means of an electric current. Mr. Ellis was 
 kind enough to grant me an interview for the purpose of explaining 
 the apparatus employed by Helmholtz in producing these extra- 
 
ELECTRIC TELEPHONY. 3 
 
 ordinary effects, and I spent the greater part of a delightful day 
 with him in investigating the subject. At that time, however, I 
 was too slightly acquainted with the laws of electricity fully to 
 understand the explanations given ; but the interview had the effect 
 of arousing my interest in the subjects of sound and electricity, and 
 I did not rest until I had obtained possession of a copy ot 
 Helmholtz' great work,* and had attempted, in a crude and im- 
 perfect manner it is true, to reproduce his results. While reflect- 
 ing upon the possibilities of the production of sound by electrical 
 means, it struck me that the principle of vibrating a tuning-fork 
 by the intermittent attraction of an electro-magnet might be 
 applied to the electrical production of music. 
 
 I imagined to myself a series of tuning-forks of different pitches, 
 arranged to vibrate automatically in the manner shown by 
 Helmholtz, each fork interrupting at every vibration a voltaic 
 current; and tHe thought occurred, " Why should not the depres- 
 sion of a key like that of a piano direct the interrupted current 
 from any one of these forks, through a telegraph wire, to a series 
 of electro-magnets operating the strings of a piano or other musical 
 instrument, in which case a person might play the tuning-fork 
 piano in one place and the music be audible from the electro- 
 magnetic piano in a distant city ?" 
 
 The more I reflected upon this arrangement the more feasible 
 did it seem to me ; indeed, I saw no reason why the depression of 
 a number of keys at the tuning-fork end of the circuit should not 
 be followed by the audible production of a full chord from the 
 piano in the distant city, each tuning-fork affecting at the receiving 
 end that string of the piano with which it was in unison. At this 
 time the interest which I felt in electricity led me to study the 
 various systems of telegraphy in use in this country and in America. 
 I was much struck with the simplicity of the Morse alphabet, and 
 with the fact that it could be read by sound. Instead of having 
 the dots and dashes recorded upon paper, the operators were in the 
 habit of observing the duration of the click of the instruments, 
 
 * Helmholtz. Die Lehrc von dein Tone/npfindungen. (English Translation 
 by Alexander J. Ellis, Theory of Tone.) 
 
 A2 
 
4 RESEARCHES IN 
 
 and in this way were enabled to distinguish by ear the various 
 signals. 
 
 It struck me that in a similar manner the duration of a musical 
 note might be made to represent the dot or dash of the telegraph 
 code, so that a person might operate one of the keys of the 
 tuning-fork piano referred to above, and the duration of the sound 
 proceeding from the corresponding string of the distant piano be 
 observed by an operator stationed there. It seemed to me that in 
 this way a number of distinct telegraph messages might be sent 
 simultaneously from the tuning-fork piano to the other end of the 
 circuit, by operators each manipulating a different key of the 
 instrument. These messages would be read by operators stationed 
 at the distant piano, each receiving operator listening for signals of 
 a certain definite pitch, and ignoring all others. In this way 
 could be accomplished the simultaneous transmission of a number 
 of telegraphic messages along a single wire, the number being 
 limited only by the delicacy of the listener's ear. The idea of 
 increasing the carrying power of a telegraph wire in this way took 
 complete possession of my mind, and it was this practical end that 
 I had in view when I commenced my researches in Electric 
 Telephony. 
 
 In the progress of science it is universally found that complexity 
 leads to simplicity, and in narrating the history of scientific re- 
 search it is often advisable to begin at the end. 
 
 In glancing back over my own researches I find it necessary to 
 designate, by distinct names, a variety of electrical currents by 
 means of which sounds can be produced, and I shall direct your 
 attention to several distinct species of what may be termed 
 u telephonic " currents of electricity. In order that the peculiari- 
 ties of these currents may be clearly understood, I shall ask Mr. 
 Frost to project upon the screen a graphical illustration of the 
 different varieties. 
 
 The graphical method of representing electrical currents here 
 shown is the best means I have been able to devise of studying in 
 an accurate manner the effects produced by various forms of tele- 
 phonic apparatus, and it has led me to the conception of that 
 peculiar species of telephonic current here designated as undu- 
 
ELECTRIC TELEPHONY. 
 
 In.tory, which has rendered feasible the artificial production of 
 articulate speech by electrical means. 
 
 Direct 
 
 
 ^ 
 
 
 Fig. 1. 
 
 A horizontal line (</ g') is taken as the zero of current, and im- 
 pulses of positive electricity are represented above the zero line, and 
 negative impulses below it, or vice versa. 
 
 The vertical thickness of any electrical impulse (b or c?), measured 
 from the zero line, indicates the intensity of the electrical current 
 at the point observed, and the horizontal extension of the electric 
 line (b or d) indicates the duration of the impulse. 
 
 Nine varieties of telephonic currents may be distinguished, but 
 it will only be necessary to show you six of these. The three pri- 
 mary varieties designated as a intermittent," " pulsatory," and 
 u undulatory," are represented in lines 1, 2, and 3. 
 
 Sub-varieties of these can be distinguished as " direct" or 
 " reversed" currents according as the electrical impulses are all 
 of one kind or are alternately positive and negative. " Direct " 
 currents may still further be distinguished as "positive" or 
 " negative," according as the impulses are of one kind or of the 
 other. 
 
 An intermittent current is characterised by the alternate presence 
 and absence of electricity upon the circuit ; 
 
 A pulsatory current results from sudden or instantaneous changes 
 in the intensity of a continuous current ; and 
 
 An undulatory current is a current of electricity, the intensity of 
 which varies in a manner proportional to the velocity of the motion 
 of a particle of air during the production of a sound : thus the curve 
 representing graphically the undulatory current for a simple musical 
 tone is the curve expressive of a simple pendulous vibration thnt 
 is, a sinusoidal curve. 
 
RESEARCHES IN 
 
 Intermittent 
 
 Pulsatory 
 
 Undulatory 
 
 Direct 
 
 Direct 
 
 Direct 
 
 Positive 1 Positive intermittent current. 
 
 Negative 2 Negative 
 
 Reversed 3 Reversed 
 
 Positive 4 Positive pulsatory current. 
 
 Negative 5 Negative ,, 
 
 Reversed 6 Reversed 
 
 Positive 7 Positive undulatory current. 
 
 Negative 8 Negative ,, 
 
 Reversed 9 Reversed 
 
 And here I may remark, that, although the conception of the 
 undulatory current of electricity is entirely original with myself, 
 methods of producing sound by means of intermittent and pulsatory 
 currents have long been known. For instance, it was long since 
 discovered that an electro-magnet gives forth a decided sound when 
 it is suddenly magnetized or demagnetized. When the circuit upon 
 which it is placed is rapidly made and broken, a succession of explo- 
 sive noises proceeds from the magnet. These sounds produce upon 
 the ear the effect of a musical note when the current is interrupted a 
 sufficient number of times per second. The discovery of u Galvanic 
 Music," by Page,* in 1837, led inquirers in different parts of the world 
 almost simultaneously to enter into the field of telephonic research ; 
 and the acoustical effects produced by magnetization were carefully 
 studied by Marrian,f Beatson,| Gassiot, De la, Rive,|| Matteucci,1[ 
 
 * C. G. Page. " The Production of Galvanic Music." Silliman's Journ. 1837, 
 xxxii. p. 396 ; Silliman's Journ. July, 1837, p. 354 ; Silliman's Journ. 1838, 
 xxxiii. p. 118 ; Bibl. Univ. (new series), 1839, ii. p. 398. 
 
 f J. P. Marrian. Phil. Mag. xxv. p. 382 ; Inst. 1845, p. 20 ; Arch, de 1'Electr. 
 v. p. 195. 
 
 I W. Beatson. Arch, de 1'Electr. v. p. 197 ; Arch, de Sc. Phys. et Nat. (2d 
 series), ii. p. 113. 
 
 Gassiot. See " Treatise on Electricity," by De la Rive, i. p. 300. 
 
 || De la Rive. Treatise on Electricity, i. p. 300 ; Phil. Mag. xxxv. p. 422 ; 
 Arch, de 1'Electr. v. p. 200 ; Inst. 1846, p. 83 ; Comptes Renclus, xx. p. 1287 ; 
 Comp. Rend. xxii. p. 432 ; Pogg. Ann. Ixxvi. p. 637 ; Ann. de Chim. et de Phys. 
 xxvi. p. 158. 
 
 f Mattcucci. Inst. 1845, p. 315 ; Arch, de 1'Electr. v. 389, 
 
. ELECTRIC TELEPHONY. 7 
 
 G-uillemin,* Wertheim,f Wartmann,J Janniar, Joule, || Laborde,H 
 Legat,** Eeis,ft Poggendorff,|| Du Moncel, Delezenne,|||| and 
 others.lHf It should also be mentioned that Gore*** obtained loud 
 musical notes from mercury, accompanied by singularly beautiful 
 crispations of the surface during the course of experiments in 
 electrolysis ; Page f ft produced musical tones from Trevelyan's 
 bars by the action of the galvanic current; and further it was dis- 
 covered by Sullivan t|| that a current of electricity is generated by 
 the vibration of a wire composed partly of one metal and partly of 
 another. The current was produced so long as the wire emitted 
 a musical note, but stopped immediately upon the cessation of the 
 sound. 
 
 For several years my attention was almost exclusively directed 
 
 * Guillemin. Comp. Rend. xxii. p. 264 ; Inst. 1846, p. 30; Arch. d. Sc. Phys. 
 (2d series), i. p. 191. 
 
 f G. Wertheim. Comp. Rend. xxii. pp. 336, 544 ; Inst. 1846, pp. 65, 100 ; Pogg. 
 Ann. Ixviii. p. 140 ; Comp. Rend. xxvi. p. 505 ; Inst. 1848, p. 142 ; Ann. de Chim. 
 et de Phys., xxiii. p. 302 ; Arch. d. Sc. Phys. et Nat. viii. p. 206 ; Pogg. Ann. 
 Ixxvii. p. 43 ; Berl. Ber. iv. p. 121. 
 
 J JBlie Wartmann. Comp. Rend. xxii. p. 544 ; Phil. Mag. (3d series), xxviii. 
 p. 544 ; Arch. d. Sc. Phys. et Nat. (2d series), i. p. 419 ; Inst. 1846, p. 290 ; 
 Monatscher. d. Berl. Akad. 1846, p. 111. 
 
 Janniar. Comp. Rend, xxiii. p. 319 ; Inst. 1846, p. 269 ; Arch. d. Sc. 
 Phys. et Nat. (2d. series), ii. p. 394. 
 
 || J. P. Joule. Phil. Mag. xxv. pp. 76, 225 ; Berl. Ber. iii. p. 489. 
 
 ^f Laborde. Comp. Rend. 1. p. 692 ; Cosmos, xyii. p. 514. 
 
 ** Legat. Brix. Z. S. ix. p. 125. 
 
 ft Reis. " Telephonic." Polytechnic Journ. clxviii. p. 185 ; Bottger's Notizbl. 
 1863, No. 6. 
 
 H J. C. Poggendorff. Pogg. Ann. xcviii. p. 192 ; Berliner Monatsber. 1856, 
 p. 133 ; Cosmos, ix. p. 49 ; Berl. Ber. xii. p. 241 ; Pogg. Ann. Ixxxvii. p. 139. 
 
 Du Moncel. Expose, ii. p. 125 ; also, iii. p. 83. 
 
 Illl Delczenne. "Sound produced by Magnetization," Bibl. Univ. (new series), 
 1841, xvi. p. 406. 
 
 *|^[ See London Journ. xxxii. p. 402 ; Polytechnic Journ. ex. p. 16 ; Cosmos, 
 
 iv. p. 43 ; Glosener Traite general, &c. p. 350 ; Dove.-Repert. vi. p. 58 ; Pogg. 
 
 Ann. xliii. p. 411; Berl. Ber. i. p. 144; Arch. d. Sc. Phys. et Nat. xvi. p. 406 ; 
 Kuhn's Encyclopedia der Physik, pp. 1014-1021. 
 
 *** Gore. Proceedings of Royal Society, xii. p. 217. 
 
 tft C. G. Page. " Vibration of Trevelyan's bars by the galvanic current." Silli- 
 man's Journal, 1850, ix. pp. 105-108. 
 
 itJ Sullivan. " Currents of Electricity produced by the vibration of Metals," 
 Phil. Mag. 1845, p. 261 ; Arch, de 1'Electr. x. p. 480, 
 
RESEARCHES IN 
 
 to the production of an instrument for making and breaking a 
 voltaic circuit with extreme rapidity, to take the place of the 
 transmitting tuning-fork used in Helmholtz' researches. I will 
 not trouble you with the description of all the various forms of 
 apparatus that were devised, but will merely direct your attention 
 
 Fig. 2. 
 
 to one of the best of them, shown in fig. 2. In the transmitting 
 instrument T, a steel reed a is employed, which is kept in con- 
 tinuous vibration by the action of an electro-magnet e and local 
 battery. In the course of its vibration the reed strikes alternately 
 against two fixed points w, I, and thus completes alternately a local 
 and a main circuit. When the key K is depressed an intermittent 
 current from the main battery B is directed to the line- wire W, and 
 passes through the electro-magnet E of a receiving instrument R at 
 the distant end of the circuit, and thence to the ground Gr. The steel 
 reed A is placed in front of the receiving magnet, and when its 
 normal rate of vibration is the same as the reed of the transmitting 
 instrument it is thrown into powerful vibration, emitting a musical 
 tone of a similar pitch to that produced by the reed of the trans- 
 mitting instrument, but if it is normally of a different pitch it 
 remains silent. 
 
 A glance at figs. 3, 4, and 5 will show the arrangement of 
 such instruments upon a telegraphic circuit, designed to enable 
 a number of telegraphic despatches to be transmitted simultaneously 
 
ELECTRIC TELEPHONY. 
 
 
 eo 
 bi 
 
10 
 
 KESEARCHES IN 
 
 along the same wire. The transmitters and receivers that are 
 numbered alike have the same pitch or rate of vibration. Thus the 
 reed of T' is in unison with the reeds Y and R' at all the stations 
 upon the circuit, so that a telegraphic despatch sent by the 
 manipulation of the key K' at the station shown in fig. 3 will 
 be received upon the receiving instruments K 7 at all the other 
 stations upon the circuit. Without going into details, I shall 
 merely say that the great defects of this plan of multiple telegraphy 
 were found to consist, firstly, in the fact that the receiving operators 
 were required to possess a good musical ear in order to discriminate 
 the signals ; and secondly, that the signals could only pass in one 
 direction along the line (so that two wires would be necessary 
 in order to complete communication in both directions). The 
 first objection was got over by employing the device which I term 
 a "vibratory circuit-breaker," shown in the next diagram, whereby 
 musical signals can be automatically recorded. 
 
 Fig. 6 shows a receiving instrument R, with a vibratory circuit- 
 breaker v attached. The light spring-lever v overlaps the free 
 end of the steel reed A, and normally closes a local circuit, in 
 which may be placed a Morse-sounder or other telegraphic appa- 
 ratus. When the reed A is thrown into vibration by the passage 
 of a musical signal, the spring arm v is thrown upwards, opening 
 the local circuit at the point 5. When the spring-arm v is so 
 
 Fig. 6. 
 
 arranged as to have normally a much slower rate of vibration than 
 the reed A 1? the local circuit is found to remain permanently open 
 during the vibration of A, the spring-arm v coming into contact 
 with the point 5 only upon the cessation of the receiver's vibra- 
 tion. Thus the signals produced by the vibration of the reed A 
 
ELECTRIC TELEPHONY. 
 
 11 
 
 are reproduced upon an ordinary telegraphic instrument in the 
 local circuit. 
 
 Fig. 7 shows the application of electric telephony to auto- 
 graphic telegraphy. 
 
 T, T', &c., represent the reeds of transmitting instruments of 
 different pitch, B, R', &c., the receivers at the distant station 
 of corresponding pitch, and, r 9 /, &c., the vibratory circuit- 
 breakers attached to the receiving instruments, and connected with 
 metallic bristles, 21, resting upon chemically prepared paper P. 
 The message, or picture, to be copied, is written upon a metallic 
 surface, Fo, with non -metallic ink, and placed upon a metallic 
 cylinder 7, connected with the main battery B; and the chemically 
 prepared paper P, upon which the message is to be received, is 
 placed upon a metallic cylinder connected with the local battery B' 
 at the receiving station. When the cylinders at either end of the 
 circuit are rotated in the direction of the arrows but not necessarily 
 at the same rate of speed a fac simile of whatever is written or 
 drawn upon the metallic surface Fo appears upon the chemically 
 prepared paper P. 
 
 The method by means of which the musical signals may be sent 
 
12 RESEARCHES IN 
 
 simultaneously in both directions along the same circuit is shown 
 in our next illustration, figures 8, 9, and 10. The arrangement is 
 similar to that shown in figures 3, 4, and 5, excepting that the 
 intermittent current from the transmitting instruments is passed 
 through the primary wires of an induction coil, and the receiving 
 instruments are placed in circuit with the secondary wire. In this 
 way free earth communication is secured at either end of the 
 circuit, and the musical signals produced by the manipulation of 
 any key are received at all the stations upon the line. The great 
 objection to this plan is the extreme complication of the parts and 
 the necessity of employing local and main batteries at every 
 station. It was also found by practical experiment that it was 
 difficult, if not impossible, upon either of the plans here shown, to 
 transmit simultaneously the number of musical tones that theory 
 showed to be feasible. Mature consideration revealed the fact that 
 this difficulty lay in the nature of the electrical current employed, 
 and was finally obviated by the invention of the undulatory 
 current. 
 
 It is a strange fact that important inventions are often made almost 
 simultaneously by different persons in different parts of the world, 
 and the idea of multiple telegraphy as developed in the preceding 
 diagrams seems to have occurred independently to no less than 
 four other inventors in America and Europe. Even the details of 
 the arrangements upon circuit shown in figures 3, 4, 5, and 8, 9, 
 10 are extremely similar in the plans proposed by Mr. Cromwell 
 Varley of London, Mr. Elisha Gray of Chicago, Mr. Paul La 
 Cour of Copenhagen, and Mr. Thomas Edison of Newark, New 
 Jersey. Into the question of priority of invention, of course, it is 
 not my intention to go to-night. 
 
 That the difficulty in the use of an intermittent current may be 
 more clearly understood, I shall ask you to accompany me in my 
 explanation of the effect produced when two musical signals of 
 different pitch are simultaneously directed along the same circuit. 
 Fig. 11 shows an arrangement whereby the reeds a a' of two 
 transmitting instruments are caused to interrupt the current from 
 the same battery, B. We shall suppose the musical interval 
 between the two reeds to be a major third, in which case their 
 
ELECTRIC TELEPHONY. 
 
 IS 
 
 * 
 
 
 00 
 
 bb 
 
14 
 
 RESEARCHES 
 
 vibrations are in the ratio of 4 to 5, i.e., 4 vibrations of a are made 
 in the same time as 5 vibrations of a'. A 2 and B 2 represent the 
 
 Fig. 11. 
 
 intermittent currents produced, 4 impulses of B 2 being made in 
 the same time as 5 impulses of A 2 . The line A 2 + B 2 represents 
 the resultant effect upon the main line when the reeds a and a 1 
 are simultaneously caused to make and break the same circuit, and 
 from the illustration you will perceive that the resultant current, 
 whilst retaining a uniform intensity, is less interrupted when 
 both reeds are in operation than when one alone is employed. By 
 carrying your thoughts still further you will understand that 
 when a large number of reeds of different pitch or of different 
 rates of vibration are simultaneously making and breaking the 
 same circuit the resultant effect upon the main line is practically 
 equivalent to one continuous current. 
 
 It will also be understood that the maximum number of musical 
 signals that can be simultaneously directed along a single wire 
 without conflict depends very much upon the ratio which the 
 " make " bears to the " break; " the shorter the contact made, and 
 the longer the break, the greater the number of signals that can 
 be transmitted without confusion, and vice versa. The apparatus 
 by means of which this theoretical conclusion has been verified is 
 here to-night, and consists of an ordinary parlour harmonium, the 
 reeds of which are operated by wind in the usual manner. In front of 
 each reed is arranged a metal screw, against which the reed strikes 
 in the course of its vibration. By adjusting the screw the duration 
 
ELECTRIC TELEPHONY. 
 
 15 
 
 of the contact can be made long or short. The reeds are connected 
 with one pole of a battery, and the screws against which they strike 
 communicate with the line-wire, so that intermittent impulses from 
 the battery are transmitted along the line-wire during the vibration 
 of the reeds. 
 
 We now proceed to the next illustration. Without entering into 
 
 Fig. 12.' 
 
 the details of the calculation you will see that with a pulsatory 
 current the effect of transmitting musical signals simultaneously is 
 nearly equivalent to a continuous current of minimum intensity see 
 A 2 + B 2 , fig. 12 ; but when undulatory currents are employed the 
 effect is different see fig. 13. The current from the battery B is 
 
 Fig. 13. 
 
 thrown into waves by the inductive action of iron or steel reeds M M', 
 vibrated in front of electro-magnets e e' 9 placed in circuit with the 
 battery ; A' 2 and B 2 represent the undulations caused in the current 
 
1C 
 
 RESEARCHES IN 
 
 by the vibration of the magnetised bodies, and it will be seen that 
 there are four undulations of B' 2 in the same time as five undulations 
 of A' 2 . The resultant effect upon the main line is expressed by 
 the curve A 2 -fB 2 , which is the algebraical sum of the sinusoidal 
 curves A' 2 and B 2 . A similar effect is produced when reversed 
 undulatory currents are employed as shown in fig. 14, where the 
 current is produced by the vibration of permanent magnets M M' 
 in front of electro-magnets (e e'\ united upon a circuit without a 
 voltaic battery. It will be understood from figs. 13 and 14 that 
 
 Fig. 14. 
 
 the effect of transmitting musical signals of different pitches simul- 
 taneously along a single wire is not to obliterate the vibratory 
 character of the current as in the case of intermittent and pulsatory 
 currents, but to change the shapes of the electrical undulations. 
 In fact, the effect produced upon the current is precisely analogous 
 to the effect produced in the air by the vibration of the inducing 
 bodies M M'. Hence it should be possible to transmit as many 
 musical tones simultaneously through a telegraph wire as through 
 the air. The possibility of using undulatory currents for the pur- 
 poses of multiple telegraphy enabled me to dispense entirely with 
 the complicated arrangements of the circuit shown in figs. 3, 4, 5, 
 and 8, 9, 10, and to employ a single battery for the whole circuit, 
 retaining only the receiving instruments formerly shown. This 
 arrangement is represented in figs. 15, 16, and 17. Upon vibrating 
 the steel reed of a receiver R, IT, at any station by any mechanical 
 means, the corresponding reeds at all the other stations are thrown 
 
ELECTRIC TELEPHONY. 
 
 17 
 
 S 
 
 >0 
 I I 
 
 fcJD 
 
18 RESEARCHES IN 
 
 into vibration, reproducing the signal. By attaching the steel reeds to 
 the poles of a powerful permanent magnet, as shown in fig. 19, the 
 signals can be produced without the aid of a battery. 
 
 I have formerly stated that Helmholtz was enabled to produce 
 vowel sounds artificially by combining musical tones of different 
 pitches and intensities. His apparatus is shown in fig. 18. Tuning- 
 
 Fig. 18.* 
 
 forks of different pitch are placed between the poles of electro- 
 magnets (a 1 , a' 2 , &c.), and are kept in continuous vibration by the 
 action of an intermittent current from the fork b. Resonators 
 1, 2, 3, &c. are arranged so as to reinforce the sounds, in a greater 
 or less degree, according as the exterior orifices are enlarged or 
 contracted. 
 
 Thus it will be seen that upon Helmholtz's plan the tuning- 
 forks themselves produce tones of uniform intensity, the loudness 
 being varied by an external reinforcement ; but it struck me that 
 the same results would be obtained, and in a much more perfect 
 manner, by causing the tuning-forks themselves to vibrate with 
 different degrees of amplitude. I therefore devised the apparatus 
 shown in fig. 19, which was my first form of articulating telephone. 
 In this figure a harp of steel rods is employed attached to the poles 
 of a permanent magnet N.S. When any one of the rods is thrown 
 into vibration an undulatory current is produced in the coils of the 
 electro-magnet E, and the electro-magnet E' attracts the rods of 
 
 * The full description of this figure will be found in Mr. Alexander J. Ellis'a 
 translation of Helmholtz's work, " Theory of Tone." 
 
ELECTEIC TELEPHONY. 19 
 
 the harp H' with a varying force, throwing into vibration that rod 
 which is in unison with that vibrated at the other end of the circuit. 
 Not only so, but the amplitude of vibration in the one will determine 
 
 Fig. 19. 
 
 the amplitude of vibration in the other, for the intensity of the 
 induced current is determined by the amplitude of the inducing vibra- 
 tion, and the amplitude of the vibration at the receiving end depends 
 upon the intensity of the attractive impulses. When we sing into 
 a piano, certain of the strings of the instrument are set in vibration 
 sympathetically by the action of the voice with different degrees of 
 amplitude, and a sound, which is an approximation to the vowel 
 uttered, is produced from the piano. Theory shows, that, had the 
 piano a very much larger number of strings to the octave, the 
 vowel sounds would be perfectly reproduced. My idea of the 
 action of the apparatus, shown in fig. 19, was this : Utter a sound 
 in the neighbourhood of the harp H, and certain of the rods would 
 be thrown into vibration with different amplitudes. At the other 
 end of the circuit the corresponding rods of the harp H' would 
 vibrate with their proper relations of force, and the timbre of the 
 sound would be reproduced. The expense of constructing such an 
 apparatus as that shown in fig. 19 deterred me from making the 
 attempt, and I sought to simplify the apparatus before venturing to 
 have it made. 
 
 I have before alluded to the invention by my father of a system 
 of physiological symbols for representing the action of the vocal 
 organs, and I had been invited by the Boston Board of Education 
 to conduct a series of experiments with the system in the Boston 
 school for the deaf and dumb. It is well known that deaf mutes 
 are dumb merely because they are deaf, and that there is no defect 
 
 B 2 
 
20 RESEARCHES IN 
 
 in their vocal organs to incapacitate them from utterance. Hence 
 it was thought that my father's system of pictorial symbols, popu- 
 larly known as visible speech, might prove a means whereby we 
 could teach the deaf and dumb to use their vocal organs and to 
 speak. The great success of these experiments urged upon me the 
 advisability of devising methods of exhibiting the vibrations of 
 sound optically, for use in teaching the deaf and dumb. For some 
 time I carried on experiments with the manometric capsule of 
 Koenig, and with the phonautograph of Leon Scott. The scientific 
 apparatus in the Institute of Technology in Boston was freely 
 placed at my disposal for these experiments, and it happened that 
 at that time a student of the Institute of Technology, Mr. Maurey, 
 had invented an improvement upon the phonautograph. He had 
 succeeded in vibrating by the voice a stylus of wood about a foot 
 in length which was attached to the membrane of the phonauto- 
 graph, and in this way he had been enabled to obtain enlarged 
 tracings upon a plane suface of smoked glass. With this apparatus 
 I succeeded in producing very beautiful tracings of the vibrations 
 of the air for vowel sounds. Some of these tracings are shown in 
 fig. 20. I was much struck with this improved form of appara- 
 
 r 
 
 VWWVVW\A/VWVWWWV\VV/VVVVV\A^ 
 
 f 
 
ELECTKIC TELEPHONY. 21 
 
 tus, and it occurred to me that there was a remarkable likeness 
 between the manner in which this piece of wood was vibrated 
 by the membrane of the phonautograph and the manner in which 
 the ossiculce of the human ear were moved by the tympanic mem- 
 brane. I determined therefore to construct a phonautograph modelled 
 still more closely upon the mechanism of the human ear, and for 
 this purpose 1 sought the assistance of a distinguished aurist in 
 Boston, Dr. Clarence J. Blake. He suggested the use of the human 
 ear itself as a phonautograph, instead of making an artificial imita- 
 tion of it. The idea was novel and struck me accordingly, and I 
 requested my friend to prepare a specimen for me, which he did. 
 The apparatus, as finally constructed, is shown in fig. 21. The 
 
 Fig. 21. 
 
 stapes was removed and a stylus of hay about an inch in length 
 was attached to the end of the incus. Upon moistening the 
 rnembrana-tympani and the ossiculas with a mixture of glycerine 
 and water, the necessary mobility of the parts was obtained ; and 
 upon singing into the external artificial ear the stylus of hay was 
 thrown into vibration, and tracings were obtained upon a plane 
 
22 
 
 RESEARCHES IN 
 
 surface of smoked glass passed rapidly underneath. While engaged 
 in these experiments I was struck with the remarkable dispropor- 
 tion in weight between the membrane and the bones that were 
 vibrated by it. It occurred to me that if a membrane as thin as 
 tissue paper could control the vibration of bones that were, com- 
 pared to it, of immense size and weight, why should not a larger 
 and thicker membrane be able to vibrate a piece of iron in front of 
 an electro-magnet, in which case the complication of steel rods 
 shown in my first form of telephone, fig. 19, could be done away 
 with, and a simple piece of iron attached to a membrane be placed 
 at either end of the telegraphic circuit. 
 
 Fig. 22 shows the form of apparatus that I was then employing 
 for producing undulatory currents of electricity for the purposes of 
 multiple telegraphy. A steel reed A was clamped firmly by one 
 extremity to the uncovered leg h of an electro-magnet E, and the 
 free end of the reed projected above the covered leg. When the 
 reed A was vibrated in any mechanical way, the battery current 
 was thrown into waves, and electrical undulations traversed the 
 circuit B E W E', throwing into vibration the corresponding 
 reed A' at the other end of the circuit. 1 immediately proceeded to 
 
 A' 
 
 w 
 
 E 
 
 1 '. ' 
 
 
 
 Fig. 22. 
 
 ^E' 
 
 
 t _ < 
 
 put my new idea to the test of practical experiment, and for this 
 purpose I attached the reed A (fig. 23) loosely by one extremity 
 to the uncovered pole h of the magnet, and fastened the other 
 
ELECTRIC TELEPHONY. 23 
 
 extremity to the centre of a stretched membrane of goldbeaters' 
 skin n. I presumed that upon speaking in the neighbourhood of the 
 membrane n it would be thrown into vibration and cause the steel 
 reed A to move in a similar manner, occasioning undulations in 
 the electrical current that would correspond to the changes in the 
 density of the air during the production of the sound ; and I further 
 thought that the change of the intensity of the current at the 
 receiving end would cause the magnet there to attract the reed A' 
 in such a manner that it should copy the motion of the reed A, 
 in which case its movements would occasion a sound from the 
 membrane n similar in timbre to that which had occasioned the 
 original vibration. 
 
 The results, however, were unsatisfactory and discouraging. My 
 friend Mr. Thomas A. Watson, who assisted me in this first ex- 
 periment, declared that he heard a faint sound proceed from the 
 telephone at his end of the circuit, but I was unable to verify his 
 assertion. After many experiments attended by the same only 
 partially-successful results, I determined to reduce the size and 
 weight of the spring as much as possible. For this purpose I glued 
 a piece of clock spring, about the size and shape of my thumbnail, 
 firmly to the centre of the diaphragm, and had a similar instrument 
 at the other end (fig. 24) ; we were then enabled to obtain distinctly 
 audible effects. I remember an experiment made with this tele- 
 
 Fig. 24. 
 
 phone, which at the time gave me great satisfaction and delight. 
 One of the telephones was placed in my lecture-room in the Boston 
 University, and the other in the basement of the adjoining building. 
 One of my students repaired to the distant telephone to observe the 
 effects of articulate speech, while I uttered the sentence, u Do you 
 understand what I say?" into the telephone placed in the lecture- 
 
24 KESEAKCHES IN 
 
 hall. To my delight an answer was returned through the instru- 
 ment itself, articulate sounds proceeded from the steel spring 
 attached to the membrane, and I heard the sentence, " Yes, I 
 understand you perfectly." It is a mistake, however, to suppose 
 that the articulation was by any means perfect, and expectancy no 
 doubt had a great deal to do with my recognition of the sentence ; 
 still, the articulation was there, and I recognised the fact that the 
 
 Fig. 25. 
 
 indistinctness was entirely due to the imperfection of the instru- 
 ment. I will not trouble you by detailing the various stages through 
 which the apparatus passed, but shall merely say that after a time 
 I produced the form of instrument shown in fig. 25, which served 
 very well as a receiving telephone. In this condition my invention 
 was exhibited at the Centennial Exhibition in Philadelphia. The 
 telephone shown in fig. 24 was used ^as a transmitting instrument, 
 and that in fig. 25 as a receiver, so that vocal communication 
 was only established in one direction. 
 
 Another form of transmitting telephone exhibited in Philadelphia 
 intended for use with the receiving telephone (fig. 25) is re- 
 presented by fig. 26. 
 
 A platinum wire attached to a stretched membrane completed 
 a voltaic circuit by dipping into water. Upon speaking to the 
 membrane, articulate sounds proceeded from the telephone in the 
 distant room. The sounds produced by the telephone became 
 louder when dilute sulphuric acid, or a saturated solution of salt, 
 was substituted for the water. Audible effects were also produced 
 by the vibration of plumbago in mercury, in a solution of bichro- 
 mate of potash, in salt and water, in dilute sulphuric acid, and in 
 pure water. 
 
 The articulation produced from the instrument shown in fig. 25 
 was remarkably distinct, but its great defect consisted in the fact 
 that it could not be used as a transmitting instrument, and thus 
 
ELECTRIC TELEPHONY. 
 
 25 
 
 two telephones were required at each station, one for transmitting 
 and one for receiving spoken messages. 
 
 
 Fig. 26. 
 
 It was determined to vary the construction of the telephone 
 shown in fig. 24, and I sought by changing the size and tension 
 of the membrane, the diameter and thickness of the steel spring, 
 the size and power of the magnet, and the coils of insulated wire 
 around their poles, to discover empirically the exact effect of each 
 element of the combination, and thus to deduce a more perfect 
 form of apparatus. It was found that a marked increase in the 
 loudness of the sounds resulted from shortening the length of the 
 coils of wire, and by enlarging the iron diaphragm which was 
 glued to the membrane. In the latter case, also, the distinctness 
 of the articulation was improved. Finally, the membrane of gold- 
 beaters' skin was discarded entirely, and a simple iron plate was 
 used instead, and at once intelligible articulation was obtained. 
 The new form of instrument is that shown in fig. 27, and, as had 
 been long anticipated, it was proved that the only use of the 
 battery was to magnetize the iron core of the magnet, for the 
 effects were equally audibble when the battery was omitted and a 
 rod of magnetized steel substituted for the iron core of the magnet. 
 
RESEARCHES IN 
 
 It was my original intention, as shown in fig. 19, and it was 
 always claimed by me, that the final form of telephone would be 
 
 Fig. 27. 
 
 operated by permanent magnets in place of batteries, and numerous 
 experiments had been carried on by Mr. Watson and myself 
 privately for the purpose of producing this effect. 
 
 At the time the instruments were first exhibited in public the 
 results obtained with permanent magnets were not nearly so 
 striking as when a voltaic battery was employed, wherefore we 
 thought it best to exhibit only the latter form of instrument. 
 
 The interest excited by the first published accounts of the opera- 
 tion of the telephone led many persons to investigate the subject, 
 and I doubt not that numbers of experimenters have independently 
 discovered that permanent magnets might be employed instead of 
 voltaic batteries. Indeed one gentleman, Professor Dolbear, of 
 Tufts Colle'ge, not only claims to have discovered the magneto- 
 electric telephone, but I understand charges me with having ob- 
 tained the idea from him through the medium of a mutual friend. 
 
 A still more powerful form of apparatus was constructed by 
 using a powerful compound horse- shoe magnet in place of the 
 straight rod which had been previously used (see fig. 28). Indeed 
 
 Fig. 28. 
 
ELECTRIC TELEPHONY. 
 
 the sounds produced by means of this instrument were of sufficient 
 loudness to be faintly audible to a large audience, and in this con- 
 dition the instrument was exhibited in the Essex Institute, in 
 Salem, Massachusetts, on the 12th Feb. 1877, on which occasion a 
 short speech shouted into a similar telephone in Boston, sixteen 
 miles away, was heard by the audience in Salem. The tones of the 
 speaker's voice were distinctly audible to an audience of 600 people, 
 but the articulation was only distinct at a distance of about 6 feet. 
 On the same occasion, also, a report of the lecture was transmitted 
 
 Fig. 29. 
 
 by word of mouth from Salem to Boston, and published in the 
 papers the next morning. 
 
 From the form of telephone shown in fig. 27 to the present form 
 of the instrument (fig. 29) is but a step. It is in fact the arrange- 
 ment of fig. 27 in a portable form, the magnet F H being placed 
 inside the handle and a more convenient form of mouthpiece pro- 
 vided. The arrangement of these instruments upon a* telegraphic 
 circuit is shown in fig. 30. 
 
 Fig. 30. 
 
 And here I wish to express my indebtedness to several 
 scientific friends in America for their co-operation and assistance. 
 
28 RESEARCHES IN 
 
 I would specially mention Professor Peirce and Professor Blake, 
 of Brown University, Dr. Charming, Mr. Clarke, and Mr. 
 Jones. In Providence, Rhode Island, these gentlemen have 
 been carrying on together experiments seeking to perfect 
 the form of apparatus required, and I am happy to record 
 the fact that they communicated to me each new discovery as it 
 was made, and every new step in their investigations. It was, 
 of course, almost inevitable that these gentlemen should retrace 
 much of the ground that had been gone over by me, and so it has 
 happened that many of their discoveries had been anticipated by 
 my own researches ; still, the very honourable way in which they 
 from time to time placed before me the results of their discoveries 
 entitles them to my warmest thanks and to my highest esteem. It 
 was always my belief that a certain ratio would be found between 
 the several parts of a telephone, and that the size of the instrument 
 was immaterial ; but Professor Peirce was the first to demonstrate 
 the extreme smallness of the magnets which might be employed. 
 And here, in order to show the parallel lines in which we were work- 
 ing, I may mention the fact that two or three days after I had con- 
 structed a telephone of the portable form (fig. 29), containing the 
 magnet inside the handle, Dr. Charming was kind enough to send 
 me a pair of telephones of a similar pattern, which had been in- 
 vented by the Providence experimenters. The convenient form of 
 mouthpiece shown in fig. 29, now adopted by me, was invented 
 solely by my friend Professor Peirce. I must also express my 
 obligations to my friend and associate, Mr. Thomas A. Watson, of 
 Salem, Massachusetts, who has for two years past given me his 
 personal assistance in carrying on my researches. 
 
 In pursuing my investigations I have ever had one end in view, 
 the practical improvement of electric telegraphy ; but I have come 
 across many facts which, while having no direct bearing upon the 
 subject of telegraphy, may yet possess an interest for you.* 
 
 For instance, I have found that a musical tone proceeds from a 
 piece of plumbago or retort-carbon when an intermittent current of 
 
 * See Researches in Telephony, Trans, of American Acad. of Arts and Sciences, 
 vol. xii. p. 1. 
 
ELECTRIC TELEPHONY. 29 
 
 electricity is passed through it, and I have observed the most 
 curious audible effects produced by the passage of reversed intermit- 
 tent currents through the human body. A rheotome was placed in 
 circuit with the primary wires of an induction coil, and the fine 
 wires were connected with two strips of brass. One of these strips 
 was held closely against the ear, and a loud sound proceeded from 
 it whenever the other slip was touched with the other hand. The 
 strips of brass were next held one in each hand. The induced cur- 
 rents occasioned a muscular tremor in the fingers. Upon placing 
 my forefinger to my ear a loud crackling noise was audible, seem- 
 ingly proceeding from the finger itself. A friend who was present 
 placed my finger to his ear, but heard nothing. I requested him to 
 hold the strips himself. He was then distinctly conscious of a noise 
 (which I was unable to perceive) proceeding from hjs finger. In 
 this case a portion of the induced currents passed through the head 
 of the observer when he placed his ear against his own finger : and 
 it is possible that the sound was occasioned by a vibration of the 
 surfaces of the ear and finger in contact. 
 
 When two persons receive a shock from a Ruhmkorff's coil by 
 clasping hands, each taking hold of one wire of the coil with the 
 free hand, a sound proceeds from the clasped hands. The effect is 
 not produced when the hands are moist. When either of the two 
 touches the body of the other a loud sound comes from the parts 
 in contact. When the arm of one is placed against the arm of the 
 other, the noise produced can be heard at a distance of several feet. 
 In all these cases a slight shock is experienced so long as the con- 
 tact is preserved. The introduction of a piece of paper between 
 the parts in contact does not materially interfere with the production 
 of the sounds, but the unpleasant effects of the shock are avoided. 
 
 When an intermittent current from a Ruhmkorff's coil is passed 
 through the arms a musical note can be perceived when the ear is 
 closely applied to the arm of the person experimented upon. The 
 sound seems to proceed from the muscles of the fore-arm and from 
 the biceps muscle. Mr. Elisha Gray* has also produced audible 
 effects by the passage of electricity through the human body. 
 
 * Elisha Gray. Eng. Pat. Spec. No. 2646, Aug. 1874. 
 
30 RESEARCHES IN 
 
 An extremely loud musical note is occasioned by the spark of 
 a Kuhmkorff's coil when the primary circuit is made and broken 
 with sufficient rapidity; when two rheotomes of different pitch 
 are caused simultaneously to open and close the primary circuit 
 a double tone proceeds from the spark. 
 
 A curious discovery, which may be of interest to you, has been 
 made by Professor Blake. He constructed a telephone in which a 
 rod of soft iron, about six feet in length, was used instead of a per- 
 manent magnet. A friend sang a continuous musical tone into 
 the mouthpiece of a telephone, like that shown in fig. 29, which 
 was connected with the soft iron instrument alluded to above. It 
 was found that the loudness of the sound produced in this telephone 
 varied with the direction in which the iron rod was held, and that 
 the maximum effect was produced when the rod was in the position 
 of the dipping-needle. This curious discovery of Professor Blake 
 has been verified by myself. 
 
 When a telephone is placed in circuit with a telegraph line, the 
 telephone is found seemingly to emit sounds on its own account. 
 The most extraordinary noises are often produced, the causes of 
 which are at present very obscure. One class of sounds is pro- 
 duced by the inductive influence of neighbouring wires and by 
 leakage from them, the signals of the Morse alphabet passing over 
 neighbouring wires being audible in the telephone, and another 
 class can be traced to earth currents upon the wire, a curious 
 modification of this sound revealing the presence of defective joints 
 in the wire. 
 
 Professor Blake informs me that he has been able to use the 
 railroad track for conversational purposes in place of a telegraph- 
 wire, and he further states that when only one telephone was con- 
 nected with the track the sounds of Morse operating were distinctly 
 audible in the telephone, although the nearest telegraph-wires 
 were at least forty feet distant. 
 
 Professor Peirce has observed the most curious sounds produced 
 from a telephone in connection with a telegraph-wire during the 
 aurora borealis ; and I have just heard of a curious phenomenon 
 lately observed by Dr. Channing. In the city of Providence, 
 Rhode Island, there is an overhouse wire about one mile in extent 
 
ELECTRIC TELEPHONY. 31 
 
 with a telephone at either end. On one occasion the sound of 
 music and singing was faintly audible in one of the telephones. 
 It seemed as if some one were practising vocal music with a piano- 
 forte accompaniment. The natural supposition was that experi- 
 ments were being made with the telephone at the other end of the 
 circuit, but upon inquiry this proved not to have been the case. 
 Attention having thus been directed to the phenomenon, a watch 
 was kept upon the instruments, and upon a subsequent occasion the 
 same fact was observed at both ends of the line by Dr. Channing 
 and his friends. It was proved that the sounds continued for 
 about two hours, and usually commenced about the same time. A 
 searching examination of the line disclosed nothing abnormal in its 
 condition, and I arn unable to give you any explanation of this 
 curious phenomenon. Dr. Channing has, however, addressed a 
 letter upon the subject to the editor of one of the Providence 
 papers, giving the names of such songs as were recognised, with 
 full details of the observations, in the hope that publicity may lead 
 to the discovery of the performer, and thus afford a solution of the 
 mystery. 
 
 My friend Mr. Frederick A. Gower communicated to me a 
 curious observation made by him regarding the slight earth con- 
 nection required to establish a circuit for the telephone, and together 
 we carried on a series of experiments with rather startling results. 
 We took a couple of telephones and an insulated wire about 100 
 yards in length into a garden, and were enabled to carry on con- 
 versation with the greatest ease when we held in our hands what 
 should have been the earth wire, so that the connection with the 
 ground was formed at either end through our bodies, our feet being 
 clothed with cotton socks and leather boots. The day was fine, and 
 the grass upon which we stood was seemingly perfectly dry. Upon 
 standing upon a gravel walk the vocal sounds, though much dimi- 
 nished, were still perfectly intelligible, and the same result occurred 
 when standing upon a brick wall one foot in height, but no sound 
 was audible when one of us stood upon a block of freestone. 
 
 One experiment which we made is so very interesting that I 
 must speak of it in detail. Mr. Gower made earth connection at 
 his end of the line by standing upon a grass plot, whilst at the 
 
32 RESEARCHES IN ELECTRIC TELEPHONY. 
 
 other end of the line I stood upon a wooden board. I requested 
 Mr. Gower to sing a continuous musical note, and to my surprise 
 the sound was very distinctly audible from the telephone in my 
 hand. Upon examining my feet I discovered that a single blade 
 of grass was bent over the edge of the board, and that my foot 
 touched it. The removal of this blade of grass was followed by the 
 cessation of the sound from the telephone, and I found that the 
 moment I touched with the toe of my boot a blade of grass or the 
 petal of a daisy the sound was again audible. 
 
 The question will naturally arise, Through what length of wire 
 can the telephone be used ? In reply to this 1 may say that the 
 maximum amount of resistance through which the undulatory 
 current will pass, and yet retain sufficient force to produce an 
 audible sound at the distant end, has yet to be determined; no 
 difficulty has, however, been experienced in laboratory experiments 
 in conversing through a resistance of 60,000 ohms, which has been 
 the maximum at my disposal. On one occasion, not having a 
 rheostat at hand, I may mention having passed the current 
 through the bodies of sixteen persons, who stood hand in hand. 
 The longest length of real telegraph line through which I have 
 attempted to converse has been about 250 miles. On this occasion 
 no difficulty was experienced so long as parallel lines were not in 
 operation. Sunday was chosen as the day on which it was pro- 
 bable other circuits would be at rest. Conversation was carried on 
 between myself, in New York, and Mr. Thomas A. Watson, in 
 Boston, until the opening of business upon the other wires. When 
 this happened the vocal sounds were very much diminished, but still 
 audible. It seemed, indeed, like talking through a storm. Con- 
 versation though possible could be carried on with difficulty, owing 
 to the distracting nature of the interfering currents. 
 
 I am informed by my friend Mr. Preece that conversation has 
 been successfully carried on through a submarine cable, sixty miles 
 in length, extending from Dartmouth to the Island of Guernsey, by 
 means of hand telephones similar to that shown in fig. 30. 
 
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